RELATED APPLICATION

[0001] This application claims the benefit of U.S. Provisional Application No. 63/238,892, filed on August 31, 2021, hereby incorporated herein in its entirety by reference.

TECHNICAL FIELD

[0002] The present disclosure relates generally to integrated circuits and integrated circuit operation, and, in particular, in one or more embodiments, the present disclosure relates to memory array structures having multiple sub-blocks, apparatus containing such memory array structures, and operation of such apparatus.

BACKGROUND

[0003] Integrated circuit devices traverse a broad range of electronic devices. One particular type include memory devices, oftentimes referred to simply as memory. Memory devices are typically provided as internal, semiconductor, integrated circuit devices in computers or other electronic devices. There are many different types of memory including random-access memory (RAM), read only memory (ROM), dynamic random access memory (DRAM), synchronous dynamic random access memory (SDRAM), and flash memory.

[0004] Flash memory has developed into a popular source of non-volatile memory for a wide range of electronic applications. Flash memory typically use a one-transistor memory cell that allows for high memory densities, high reliability, and low power consumption. Changes in threshold voltage (Vt) of the memory cells, through programming (which is often referred to as writing) of charge storage structures (e.g., floating gates or charge traps) or other physical phenomena (e.g., phase change or polarization), determine the data state (e.g., data value) of each memory cell. Common uses for flash memory and other non-volatile memory include personal computers, personal digital assistants (PDAs), digital cameras, digital media players, digital recorders, games, appliances, vehicles, wireless devices, mobile telephones, and removable memory modules, and the uses for non-volatile memory continue to expand.

[0005] A NAND flash memory is a common type of flash memory device, so called for the logical form in which the basic memory cell configuration is arranged. Typically, the array of memory cells for NAND flash memory is arranged such that the control gate of each memory cell of a row of the array is connected together to form an access line, such as a word line. Columns of the array include strings (often termed NAND strings) of memory cells connected together in series between a pair of select gates, e.g., a source select transistor and a drain select transistor. Each source select transistor might be connected to a source, while each drain select transistor might be connected to a data line, such as column bit line. Variations using more than one select gate between a string of memory cells and the source, and/or between the string of memory cells and the data line, are known.

[0006] A general trend in semiconductor memory fabrication is to increase memory density. This might be accomplished by decreasing feature sizes and/or utilizing three- dimensional array structures to increase the number of memory cells formed in a given area of a semiconductor wafer. However, such approaches have limitations.

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] Figure 1 is a simplified block diagram of a memory in communication with a processor as part of an electronic system, according to an embodiment.

[0008] Figure 2A is a schematic of a portion of an array of memory cells of the related art.

[0009] Figures 2B-2C might represent top views of an array of memory cells including a structure of the type depicted in Figure 2A, and further depicting a separation of select lines.

[0010] Figures 3A-3C are schematics of portions of an array of memory cells in accordance with embodiments as could be used in a memory of the type described with reference to Figure 1. [0011] Figure 4A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1.

[0012] Figures 4B-4C depict representations of top views of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 4A.

[0013] Figure 4D depicts a conceptualized representation of a top view of two sub-blocks of memory cells of an array of memory cells including a structure of a type similar to that depicted in Figure 4A and depicting an orientation of data lines.

[0014] Figure 5 A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1.

[0015] Figure 5B depicts a representation of a top view of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 5 A.

[0016] Figure 6A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1.

[0017] Figure 6B depicts a representation of a top view of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 6A.

[0018] Figures 7A-7F depict conceptualized representations of cross-sectional views of portions of an array structure in accordance with additional embodiments as could be used in a memory of the type described with reference to Figure 1.

[0019] Figure 8 depicts a use of varying select line thicknesses for use with embodiments.

[0020] Figures 9A-9E depict conceptualized representations of cross-sectional views of portions of an array structure in accordance with alternate embodiments as could be used in a memory of the type described with reference to Figure 1.

[0021] Figures 10A-10K depict an integrated circuit structure during various stages of fabrication in accordance with an embodiment.

[0022] Figure 11 is a flowchart of a method of operating an apparatus in accordance with an embodiment. [0023] Figure 12 is a flowchart of a method of operating an apparatus in accordance with another embodiment.

[0024] Figure 13 is a flowchart of a method of operating an apparatus in accordance with a further embodiment.

[0025] Figure 14 is a flowchart of a method of operating an apparatus in accordance with a still further embodiment.

DETAILED DESCRIPTION

[0026] In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown, by way of illustration, specific embodiments. In the drawings, like reference numerals describe substantially similar components throughout the several views. Other embodiments might be utilized and structural, logical and electrical changes might be made without departing from the scope of the present disclosure. The following detailed description is, therefore, not to be taken in a limiting sense.

[0027] The term “conductive” as used herein, as well as its various related forms, e.g., conduct, conductively, conducting, conduction, conductivity, etc., refers to electrically conductive unless otherwise apparent from the context. Similarly, the term “connecting” as used herein, as well as its various related forms, e.g., connect, connected, connection, etc., refers to electrically connecting by a conductive path unless otherwise apparent from the context.

[0028] As used herein, multiple acts being performed concurrently will mean that each of these acts is performed for a respective time period, and each of these respective time periods overlaps, in part or in whole, with each of the remaining respective time periods. In other words, portions of each of those acts are simultaneously performed for at least some period of time.

[0029] It is recognized herein that even where values might be intended to be equal, variabilities and accuracies of industrial processing and operation might lead to differences from their intended values. These variabilities and accuracies will generally be dependent upon the technology utilized in fabrication and operation of the integrated circuit device. As such, if values are intended to be equal, those values are deemed to be equal regardless of their resulting values.

[0030] Figure 1 is a simplified block diagram of a first apparatus, in the form of a memory (e.g., memory device) 100, in communication with a second apparatus, in the form of a processor 130, as part of a third apparatus, in the form of an electronic system, according to an embodiment. Some examples of electronic systems include personal computers, personal digital assistants (PDAs), digital cameras, digital media players, digital recorders, games, appliances, vehicles, wireless devices, mobile telephones and the like. The processor 130, e.g., a controller external to the memory device 100, might be a memory controller or other external host device.

[0031] Memory device 100 includes an array of memory cells 104 that might be logically arranged in rows and columns. The array of memory cells 104 might contain array structures in accordance with one or more embodiments. Memory cells of a logical row are typically connected to the same access line (commonly referred to as a word line) while memory cells of a logical column are typically selectively connected to the same data line (commonly referred to as a bit line). A single access line might be associated with more than one logical row of memory cells and a single data line might be associated with more than one logical column. Memory cells (not shown in Figure 1) of at least a portion of array of memory cells 104 are capable of being programmed to one of at least two target data states.

[0032] A row decode circuitry 108 and a column decode circuitry 110 are provided to decode address signals. Address signals are received and decoded to access the array of memory cells 104. Memory device 100 also includes input/output (I/O) control circuitry 112 to manage input of commands, addresses and data to the memory device 100 as well as output of data and status information from the memory device 100. An address register 114 is in communication with I/O control circuitry 112 and row decode circuitry 108 and column decode circuitry 110 to latch the address signals prior to decoding. A command register 124 is in communication with I/O control circuitry 112 and control logic 116 to latch incoming commands.

[0033] A controller (e.g., the control logic 116 internal to the memory device 100) controls access to the array of memory cells 104 in response to the commands and might generate status information for the external processor 130, i.e., control logic 116 is configured to perform access operations (e.g., sensing operations [which might include read operations and verify operations], programming operations and/or erase operations) on the array of memory cells 104. The control logic 116 is in communication with row decode circuitry 108 and column decode circuitry 110 to control the row decode circuitry 108 and column decode circuitry 110 in response to the addresses. The control logic 116 might include instruction registers 128 which might represent computer-usable memory for storing computer-readable instructions. For some embodiments, the instruction registers 128 might represent firmware. Alternatively, the instruction registers 128 might represent a grouping of memory cells, e.g., reserved block(s) of memory cells, of the array of memory cells 104. The control logic 116 might be configured, e.g., in response to such computer-readable instructions, to cause the memory 100 to perform methods of one or more embodiments.

[0034] Control logic 116 might further be in communication with a cache register 118. Cache register 118 latches data, either incoming or outgoing, as directed by control logic 116 to temporarily store data while the array of memory cells 104 is busy writing or reading, respectively, other data. During a programming operation (e.g., write operation), data might be passed from the cache register 118 to the data register 120 for transfer to the array of memory cells 104; then new data might be latched in the cache register 118 from the I/O control circuitry 112. During a read operation, data might be passed from the cache register 118 to the I/O control circuitry 112 for output to the external processor 130; then new data might be passed from the data register 120 to the cache register 118. The cache register 118 and/or the data register 120 might form (e.g., might form a portion of) a page buffer of the memory device 100. A page buffer might further include sensing devices (not shown in Figure 1) to sense a data state of a memory cell of the array of memory cells 104, e.g., by sensing a state of a data line connected to that memory cell. A status register 122 might be in communication with I/O control circuitry 112 and control logic 116 to latch the status information for output to the processor 130.

[0035] Memory device 100 receives control signals at control logic 116 from processor 130 over a control link 132. The control signals might include a chip enable CE#, a command latch enable CLE, an address latch enable ALE, a write enable WE#, a read enable RE#, and a write protect WP#. Additional or alternative control signals (not shown) might be further received over control link 132 depending upon the nature of the memory device 100. Memory device 100 receives command signals (which represent commands), address signals (which represent addresses), and data signals (which represent data) from processor 130 over a multiplexed input/output (I/O) bus 134 and outputs data to processor 130 over I/O bus 134.

[0036] For example, the commands might be received over input/output (I/O) pins [7:0] of I/O bus 134 at I/O control circuitry 112 and might then be written into command register 124. The addresses might be received over input/output (I/O) pins [7:0] of I/O bus 134 at I/O control circuitry 112 and might then be written into address register 114. The data might be received over input/output (I/O) pins [7:0] for an 8-bit device or input/output (I/O) pins [15:0] for a 16-bit device at I/O control circuitry 112 and then might be written into cache register 118. The data might be subsequently written into data register 120 for programming the array of memory cells 104. For another embodiment, cache register 118 might be omitted, and the data might be written directly into data register 120. Data might also be output over input/output (I/O) pins [7:0] for an 8-bit device or input/output (I/O) pins [15:0] for a 16-bit device. Although reference might be made to I/O pins, they might include any conductive nodes providing for electrical connection to the memory device 100 by an external device (e.g., processor 130), such as conductive pads or conductive bumps as are commonly used.

[0037] It will be appreciated by those skilled in the art that additional circuitry and signals can be provided, and that the memory device 100 of Figure 1 has been simplified. It should be recognized that the functionality of the various block components described with reference to Figure 1 might not necessarily be segregated to distinct components or component portions of an integrated circuit device. For example, a single component or component portion of an integrated circuit device could be adapted to perform the functionality of more than one block component of Figure 1. Alternatively, one or more components or component portions of an integrated circuit device could be combined to perform the functionality of a single block component of Figure 1.

[0038] Additionally, while specific I/O pins are described in accordance with popular conventions for receipt and output of the various signals, it is noted that other combinations or numbers of I/O pins (or other I/O node structures) might be used in the various embodiments.

[0039] Figure 2A is a schematic of a portion of an array of memory cells, such as a NAND memory array, of the related art. The array of memory cells includes access lines (e.g., word lines) 2O2o to 202N, and a data line (e.g., bit line) 204. [0040] The array of memory cells might be arranged in rows (each corresponding to an access line 202) and columns (each corresponding to a data line 204). Each column might include a string of series-connected memory cells (e.g., non-volatile memory cells), such as one of NAND strings 2O6o to 206M. Each NAND string 206 might be connected (e.g., selectively connected) to a common source (SRC) 216 and might include memory cells 2O8o to 208N. The memory cells 208 might represent non-volatile memory cells for storage of data.

[0041] The memory cells 208 of each NAND string 206 might be connected in series between a select gate 210 (e.g., a field-effect transistor), such as one of the select gates 21Oo to 210M, and a select gate 212 (e.g., a field-effect transistor), such as one of the select gates 212o to 212M. Select gates 21Oo to 210M might be commonly connected to a select line 214, such as a source select line (SGS), and select gates 212o to 212M might be connected to different select lines 218, e.g., select lines 218O-218M. A control gate of each select gate 210 might be connected to select line 214. A control gate of each select gate 212 might be connected to a respective select line 218. As used herein, a field-effect transistor, e.g., an integrated circuit device using an electric field to control the flow of current, might be alternatively referred to as a transistor.

[0042] A source of each select gate 210 might be connected to common source 216. The drain of each select gate 210 might be connected to a memory cell 208 of the corresponding NAND string 206. For example, the drain of select gate 21Oo might be connected to the source of memory cell 2O8o of the corresponding NAND string 2O6o. Therefore, each select gate 210 for a corresponding NAND string 206 might be configured to selectively connect that NAND string 206 to common source 216.

[0043] The drain of each select gate 212 might be connected to the data line 204. The source of each select gate 212 might be connected to a memory cell 208 of the corresponding NAND string 206. For example, the source of select gate 212o might be connected to memory cell 208N of the corresponding NAND string 2O6o. Therefore, each select gate 212 for a corresponding NAND string 206 might be configured to selectively connect that NAND string 206 to the data line 204.

[0044] A sub-block of memory cells 240, e.g., sub-blocks of memory cells 24OO-24OM, might each include one or more NAND strings 206 having their select gates 212 connected to a same select line 218. A block of memory cells 242 might include each sub-block of memory cells 240 sharing a same set of access lines 202. Each sub-block of memory cells 240 might have one or more respective channel material structures 244, with each channel material structure 244 forming a channel of the select gate 210, the select gate 212, and each memory cell 208 of its respective NAND string 206. For example, the channel material structure 244o might form a channel for the select gate 21Oo, the select gate 212o, and each memory cell 2O8O-2O8N of the NAND string 2O6o.

[0045] Typical construction of memory cells 208 includes a data-storage structure 236 (e.g., a floating gate, charge trap, or other structure configured to store charge) that can determine a data state of the memory cell (e.g., through changes in threshold voltage), and a control gate 238, as shown in Figure 2A. The data-storage structure 236 might include both conductive and dielectric structures while the control gate 238 is generally formed of one or more conductive materials. In some cases, memory cells 208 might further have a defined source/drain (e.g., source) 232 and a defined source/drain (e.g., drain) 234. Memory cells 208 have their control gates 238 connected to (and in some cases form) an access line 202.

[0046] Figure 2B might represent a top view of an array of memory cells including a structure of the type depicted in Figure 2A, and further depicting a separation of select lines 218 facilitated by the inclusion of dummy channel material structures 244, e.g., channel material structures 244 that are not connected to a select line 218 and thus could be inaccessible for data storage. The select lines 218o-2183 for the sub-blocks of memory cells 24Oo-24O3, respectively, are each depicted to be conductive plates, as is common in 3D NAND arrays. Although separation of the select lines 218 as depicted in Figure 2B facilitates independent selection of the sub-blocks of memory cells 240, such separation generally increases the footprint of a block of memory cells 242 due to the inclusion of dummy channel material structures 244 that do not contribute to the overall data storage capacity of the memory.

[0047] Figure 2C might represent a top view of an array of memory cells including a structure of the type depicted in Figure 2A, and further depicting a separation of select lines 218 facilitated by the use of a weave cut between the select lines 218. For example, the select gates connected to the select lines 218, e.g., select gates 212, might utilize a different structure than the memory cells 208, e.g., lacking a data storage structure and using a thinner gate dielectric. This might provide sufficient spacing between control gates to provide adequate isolation of the select lines 218. The select lines 218o-2183 for the sub-blocks of memory cells 24Oo-24O3, respectively, are each depicted to be conductive plates, as is common in 3D NAND arrays. Although separation of the select lines 218 as depicted in Figure 2C facilitates independent selection of the sub-blocks of memory cells 240, such separation might become impracticable as feature dimensions of the array structures become smaller. Various embodiments seek to facilitate independent selection of sub-blocks of memory cells 240 without separation between select lines 218.

[0048] Figure 3A is a schematic of a portion of an array of memory cells 300A, such as a NAND array of memory cells, as could be used in a memory of the type described with reference to Figure 1, e.g., as a portion of array of memory cells 104. The array of memory cells 300A includes access lines (e.g., word lines) 2O2o to 202N, and a data line (e.g., bit line) 204. The access lines 202 might be connected to global access lines (e.g., global word lines), not shown in Figure 3 A, in a many-to-one relationship. For some embodiments, the array of memory cells 300A might be formed over a semiconductor that, for example, might be conductively doped to have a conductivity type, such as a p-type conductivity, e.g., to form a p-well, or an n-type conductivity, e.g., to form an n-well.

[0049] The array of memory cells 300 A might be arranged in rows (each corresponding to an access line 202) and columns (each corresponding to a data line 204). Each column might include a string of series-connected memory cells (e.g., non-volatile memory cells), such as one of NAND strings 2O6o to 206M. Each NAND string 206 might be connected (e.g., selectively connected) to a common source (SRC) 216 and might include memory cells 2O8o to 208N. The memory cells 208 might represent non-volatile memory cells for storage of data. Some of the memory cells 208 might represent dummy memory cells, e.g., memory cells not intended to store user data. Dummy memory cells are typically not accessible to a user of the memory, and are typically incorporated into the NAND string 206 for operational advantages, as are well understood.

[0050] The memory cells 208 of each NAND string 206 might be connected in series between a select gate 210 (e.g., a transistor), such as one of the select gates 21Oo to 210M (e.g., that might be source select transistors, commonly referred to as select gate source), and two or more select gates 212 (e.g., transistors), such as one of the select gates 212oo to 212OM or 212IO-212IM (e.g., that might be drain select transistors, commonly referred to as select gate drain). Select gates 21Oo to 210M might be commonly connected to a select line 214, such as a source select line (SGS). Select gates 212oo to 212OM might be commonly connected to a select line 218o, such as a drain select line (SGDo). Select gates 212io to 212IM might be commonly connected to a select line 218i, such as a drain select line (SGDi). The select gates 212 might utilize a structure similar to (e.g., the same as) the memory cells 208. Although depicted as traditional transistors, the select gates 210 might also utilize a structure similar to (e.g., the same as) the memory cells 208. The select gates 210 and 212 might each represent a plurality of select gates connected in series, with each select gate in series configured to receive a same or independent control signal. A control gate of each select gate 210 might be connected to select line 214. A control gate of each select gate 212 might be connected to a respective select line 218.

[0051] The select gates 210 for each NAND string 206 might be connected in series between its memory cells 208 and an optional GIDL (gate-induced drain leakage) generator gate 220 (e.g., a transistor), such as one of the GIDL generator (GG) gates 22Oo to 220M. The GG gates 22Oo to 220M might be referred to as source GG gates. The source GG gates 22Oo to 220M might each be connected (e.g., directly connected) to the source 216, and selectively connected to their respective NAND strings 2O6o to 206M. Alternatively, a select gate 210 and its GG gate 220 might represent a single gate, e.g., connected (e.g., directly connected) to the source 216, and connected (e.g., directly connected) to a respective NAND string 206. The select gates 212 of each NAND string 206 might be connected in series between its memory cells 208 and pre-configured select gates 328 such as one of the pre-configured select gates 328oo to 328OM and a corresponding one of the pre-configured select gates 328 io to 328IM. Pre-configured select gates 328oo to 328OM might be commonly connected to a select line 33Oo, such as a select line SGPo. Pre-configured select gates 328 io to 328 IM might be commonly connected to a select line 330i, such as a select line SGPi. Although depicted as traditional transistors, the pre-configured select gates 328 might utilize a structure similar to (e.g., the same as) the memory cells 208. In addition, fewer or more pre-configured select gates 328 might be utilized in series. For example, where two pre-configured select gates 328 in series might be sufficient for embodiments where M is less than or equal to three, additional pre-configured select gates 328 in series might be utilized for embodiments where M is greater than three. Similarly, where two select gates 212 in series might be sufficient for embodiments where M is less than or equal to three, fewer or more select gates 212 in series might be utilized in various embodiments. [0052] A sub-block of memory cells 240, e.g., sub-blocks of memory cells 24OO-24OM, might each include one or more NAND strings 206 having their select gates 212 connected to a same select line 218. A block of memory cells 242 might include each sub-block of memory cells 240 sharing a same set of access lines 202. Each sub-block of memory cells 240 might have one or more respective channel material structures 244, with each channel material structure 244 forming a channel of the select gate 210, the select gate 212, and each memory cell 208 of its respective NAND string 206. For example, the channel material structure 244o might form a channel for the GG gate 22Oo, the select gate 21Oo, the select gate 212oo, the select gate 212io, the pre-configured select gate 328oo, the pre-configured select gate 328io, the GG gate 222o, and each memory cell 2O8O-2O8N of the NAND string 2O6o.

[0053] Each pre-configured select gate 328 might be configured, e.g., at a time of fabrication, to be either activated or deactivated in response to a control signal having a particular voltage level, e.g., they might be fabricated to have one of two different threshold voltages. Note that this results from a material difference between two pre-configured select gates 328 at a time of fabrication, and is independent of differences in threshold voltage that could result from programming operations performed after fabrication. As will be described in more detail infra, each pre-configured select gate 328 having a control gate connected to a same select line 330 might have either a first threshold voltage (Vt) or a second threshold voltage different than (e.g., lower than) the first threshold voltage. For example, transistors (e.g., select gates 210 and 212, pre-configured select gate 328, GG gates 220 and 222, and memory cells 208) formed along a channel material structure 244 might have a nominal threshold voltage that could be altered by selectively changing a concentration of a dopant impurity in the channel region. For example, doping of the channel region during fabrication might be used to alter, e.g., increase, the threshold voltage of selected pre-configured select gates 328. This doping might be used to form a channel region of a pre-configured select gate 328 to have either a first concentration of the impurity, or a second concentration of the impurity, lower than the first concentration of the impurity, at the time of fabrication. Note that the second concentration of the impurity could be devoid of the dopant impurity, e.g., undoped. The resulting difference in threshold voltages might facilitate selective programming of select gates 212 selectively connected to a same data line 204 as described infra.

[0054] The pre-configured select gates 328 for each NAND string 206 might be connected in series between its select gates 212 and an optional GG gate 222 (e.g., a transistor), such as one of the GG gates 222o to 222M. The GG gates 222o to 222M might be referred to as drain GG gates. The drain GG gates 222o to 222M might be connected (e.g., directly connected) to the data line 204, and selectively connected to their respective NAND strings 2O6o to 206M. Alternatively, a pre-configured select gate 328 and its GG gate 222 might represent a single gate, e.g., connected (e.g., directly connected) to the data line 204, and connected (e.g., directly connected) to a respective select gate 212.

[0055] GG gates 22Oo to 220M might be commonly connected to a control line 224, such as an SGS_GG control line, and GG gates 222o to 222M might be commonly connected to a control line 226, such as an SGD GG control line. Although depicted as traditional transistors, the GG gates 220 and 222 might utilize a structure similar to (e.g., the same as) the memory cells 208. The GG gates 220 and 222 might represent a plurality of GG gates connected in series, with each GG gate in series configured to receive a same or independent control signal. The GG gates 220 and 222 might be provided to assist in the generation of GIDL current into a channel region of their corresponding NAND string 206 during an erase operation, for example, as is well understood in the art.

[0056] A source of each GG gate 220 might be connected to common source 216. The drain of each GG gate 220 might be connected to a select gate 210 of the corresponding NAND string 206. For example, the drain of GG gate 22Oo might be connected to the source of select gate 21Oo of the corresponding NAND string 2O6o. Therefore, in cooperation, each select gate 210 and GG gate 220 for a corresponding NAND string 206 might be configured to selectively connect that NAND string 206 to common source 216. A control gate of each GG gate 220 might be connected to control line 224.

[0057] The drain of each GG gate 222 might be connected to the data line 204 for the corresponding NAND string 206. The source of each GG gate 222 might be connected to a pre-configured select gate 328 of the corresponding NAND string 206. For example, the source of GG gate 222o might be connected to pre-configured select gate 328 io of the corresponding NAND string 2O6o. Therefore, in cooperation, each select gate 212, preconfigured select gate 328 and GG gate 222 for a corresponding NAND string 206 might be configured to selectively connect that NAND string 206 to the data line 204.

[0058] The array of memory cells 300A in Figure 3A might be a quasi-two-dimensional array of memory cells and might have a generally planar structure, e.g., where the common source 216, NAND strings 206 and data lines 204 extend in substantially parallel planes. Alternatively, the array of memory cells 300A in Figure 3A might be a three-dimensional array of memory cells, e.g., where NAND strings 206 might extend substantially perpendicular to a plane containing the common source 216 and to a plane containing the data lines 204 that might be substantially parallel to the plane containing the common source 216.

[0059] Typical construction of memory cells 208 includes a data-storage structure 236 (e.g., a floating gate, charge trap, or other structure configured to store charge) that can determine a data state of the memory cell (e.g., through changes in threshold voltage), and a control gate 238, as shown in Figure 3A. The data-storage structure 236 might include both conductive and dielectric structures while the control gate 238 is generally formed of one or more conductive materials. In some cases, memory cells 208 might further have a defined source/drain (e.g., source) 232 and a defined source/drain (e.g., drain) 234. Memory cells 208 have their control gates 238 connected to (and in some cases form) an access line 202.

[0060] A column of the memory cells 208 might be a NAND string 206 or a plurality of NAND strings 206 selectively connected to a given data line 204. A row of the memory cells 208 might be memory cells 208 commonly connected to a given access line 202. A row of memory cells 208 can, but need not, include all memory cells 208 commonly connected to a given access line 202. Rows of memory cells 208 might often be divided into one or more groups of physical pages of memory cells 208, and physical pages of memory cells 208 often include every other memory cell 208 commonly connected to a given access line 202. Other groupings of memory cells 208 commonly connected to a given access line 202 might also define a physical page of memory cells 208. For certain memory devices, all memory cells commonly connected to a given access line 202 might be deemed a physical page of memory cells. The portion of a physical page of memory cells (which, in some embodiments, could still be the entire row) that is read during a single read operation or programmed during a single programming operation (e.g., an upper or lower page of memory cells) might be deemed a logical page of memory cells. A block of memory cells 242 might include those memory cells that are configured to be erased together, such as all memory cells connected to access lines 2O2O-2O2N (e.g., all NAND strings 206 sharing a common set of access lines 202). Unless expressly distinguished, any reference to a page of memory cells herein refers to the memory cells of a logical page of memory cells. [0061] Figure 3B is another schematic of a portion of an array of memory cells 300B as could be used in a memory of the type described with reference to Figure 1, e.g., as a portion of array of memory cells 104. Like numbered elements in Figure 3B correspond to the description as provided with respect to Figure 3A. Figure 3B provides additional detail of one example of a three-dimensional NAND array of memory cells structure. The three- dimensional NAND array of memory cells 300B might incorporate vertical structures which might include semiconductor pillars where a portion of a pillar might act as a body and a channel region of the memory cells of NAND strings 206, e.g., the channel material structure 244. The NAND strings 206 might be each selectively connected to a data line 2O4O-2O4M by respective select gates 212o and 212i and to a common source 216 by a respective select gate 210. For clarity, GG gates 220 and 222, as well as some pre-configured select gates 328, are not depicted in Figure 3B.

[0062] Multiple NAND strings 206 might be selectively connected to the same data line 204. In the example of Figure 3B, subsets of NAND strings 206 can be connected to their respective data lines 204 by biasing the select lines 218o and 218i to selectively activate particular select gates 212 each between a NAND string 206 and a data line 204. The select gates 210 can be activated by biasing the select line 214. Each access line 202 might be connected to multiple rows of memory cells of the array of memory cells 300B. Rows of memory cells that are commonly connected to each other by a particular access line 202 might collectively be referred to as tiers.

[0063] The three-dimensional NAND array of memory cells 300B might be formed over peripheral circuitry 346. The peripheral circuitry 346 might represent a variety of circuitry for accessing the array of memory cells 300B. The peripheral circuitry 346 might include complementary circuit elements. For example, the peripheral circuitry 346 might include both n-channel and p-channel transistors formed on a same semiconductor substrate, a process commonly referred to as CMOS, or complementary metal-oxide-semiconductors. Although CMOS often no longer utilizes a strict metal-oxide-semiconductor construction due to advancements in integrated circuit fabrication and design, the CMOS designation remains as a matter of convenience.

[0064] Figure 3C is another schematic of a portion of an array of memory cells 300C as could be used in a memory of the type described with reference to Figure 1, e.g., as a portion of array of memory cells 104. Like numbered elements in Figure 3C correspond to the description as provided with respect to Figure 3A. Figure 3C provides detail of one example of an array structure having more than two sub-blocks of memory cells 240.

[0065] In the array of memory cells 300C of Figure 3C, NAND strings 206 of four different sub-blocks of memory cells 24Oo-24O3 are each selectively connected to one of the data lines 2O4o-2O4i. For example, the NAND strings 206 corresponding to channel material structures 244oo-244o3 might each be selectively connected to the data line 2O4o through a respective set of select gates 212o-2123, a respective set of pre-configured select gates 328o- 328i, and a respective GG gate 222. Similarly, the NAND strings 206 corresponding to channel material structures 244IO-244B might each be selectively connected to the data line 204i through a respective set of select gates 212o-2123, a respective set of pre-configured select gates 328o-328i, and a respective GG gate 222.

[0066] In general, an array structure for a given block of memory cells 242 might include a number of select gates 212 between each NAND string 206 and a data line 204 that is equal to or greater than a number of sub-blocks of memory cells 240 of that block of memory cells 242. In addition, an array structure for a given block of memory cells 242 might include a number of pre-configured select gates 328 that is an integer value X such that 2 ^A X is equal to or greater than the number of sub-blocks of memory cells 240 of that block of memory cells 242. For example, if there are two sub-blocks of memory cells 240 in a block of memory cells 242, the number of pre-configured select gates 328 might be 1 (or more) as 2 ^A 1 is equal to 2. Similarly, if there are four sub-blocks of memory cells 240 in a block of memory cells 242, the number of pre-configured select gates 328 might be 2 (or more) as 2 ^A 2 is equal to 4. Although numbers of sub-blocks of memory cells 240 being some power of 2 generally might be preferred, embodiments can be adapted to a number of sub-blocks of memory cells 240 being other than some power of 2. For example, if there are three sub-blocks of memory cells 240 in a block of memory cells 242, the number of pre-configured select gates 328 might be 2 (or more) as 2 ^A 2 is greater than 3.

[0067] To connect a NAND string 206 for one sub-block of memory cells 240 to its data line 204 without connecting NAND strings 206 of other sub-blocks of memory cells 240 to that data line 204, the select gates 212 might be programmed to be either activated or deactivated in response to a control signal having a particular voltage level, e.g., they might be programmed to have one of two different threshold voltages. As will be described in more detail infra, each select gate 212 having a control gate connected to a same select line 218 might have either a first threshold voltage (Vt) or a second threshold voltage different than (e.g., lower than) the first threshold voltage. For example, for the select gates 212 having control gates connected to a given select line 218, those select gates 212 corresponding to one of the sub-blocks of memory cells 240 might be programmed to have a positive threshold voltage while the remaining select gates 212 having control gates connected to that select line 218 (e.g., corresponding to the remaining sub-blocks of memory cells 240) might remain unprogrammed and have a negative threshold voltage. Alternatively, for the select gates 212 having control gates connected to a given select line 218, those select gates 212 corresponding to one of the sub-blocks of memory cells 240 might be programmed to have a particular threshold voltage while the remaining select gates 212 having control gates connected to that select line 218 (e.g., corresponding to the remaining sub-blocks of memory cells 240) might be programmed and have a different, lower, threshold voltage. This configuration will be described by example with reference to the array of memory cells 300C.

[0068] In the array of memory cells 300C, the select gates 212s connected to the select line 2183 and corresponding to the sub-block of memory cells 240s might be programmed to have threshold voltages higher that each remaining select gate 212 s connected to the select line 2183 and corresponding to the sub-blocks of memory cells 24Oo-24O2. This is indicated by the thick black data storage structures of the select gates 2123 corresponding to the channel material structures 244B and 244os. In a like manner, the select gates 2122 connected to the select line 2182 and corresponding to the sub-block of memory cells 2402 might be programmed to have threshold voltages higher that each remaining select gate 2122 connected to the select line 2182 and corresponding to the sub-blocks of memory cells 24Oo, 2401 and 240s; the select gates 212i connected to the select line 2181 and corresponding to the subblock of memory cells 2401 might be programmed to have threshold voltages higher that each remaining select gate 212i connected to the select line 2181 and corresponding to the subblocks of memory cells 24Oo, 2402 and 240s; and the select gates 212o connected to the select line 2180 and corresponding to the sub-block of memory cells 24Oo might be programmed to have threshold voltages higher that each remaining select gate 212o connected to the select line 2180 and corresponding to the sub-blocks of memory cells 2401-2403.

[0069] Programming of select gates 212 might utilize an iterative process of applying a programming pulse to a programmable transistor and verifying if that transistor has reached a desired threshold voltage in response to that programming pulse, and repeating that iterative process until that transistor passes the verification. Alternatively, programming of select gates 212 might utilize a single programming pulse having a voltage level configured to increase the threshold voltage above some particular voltage level, e.g., above a voltage level to be used to activate an unprogrammed select gate 212 and deactivate a programmed select gate 212. A voltage level of a programming pulse sufficient to increase the threshold voltage of any select gate 212 above the particular voltage level might, for example, be determined experimentally, empirically or through simulation.

[0070] If the select gates 212i corresponding to the sub-block of memory cells 240 the select gates 2122 corresponding to the sub-block of memory cells 2402, the select gates 212i corresponding to the sub-block of memory cells 240i, and the select gates 212o corresponding to the sub-block of memory cells 24Oo, are programmed to have positive threshold voltages, e.g., 3V, and the remaining select gates 212 have negative threshold voltages, e.g., -IV, a control signal of 5V applied to the select line 2183 and control signals of 0V applied to the select lines 218o, 2181 and 2182 could be used to connect the NAND strings 206 of the subblock of memory cells 240s to the data lines 2O4o and 2041, and to isolate the NAND strings 206 of the sub-blocks of memory cells 24Oo, 240i and 2402 from the data lines 2O4o and 204i. Similarly, a control signal of 5V applied to the select line 2182 and control signals of 0V applied to the select lines 218o, 2181 and 2183 could be used to connect the NAND strings 206 of the sub-block of memory cells 2402 to the data lines 2O4o and 204i, and to isolate the NAND strings 206 of the sub-blocks of memory cells 24Oo, 2401 and 240s from the data lines 2O4o and 204i. Likewise, a control signal of 5V applied to the select line 2181 and control signals of 0V applied to the select lines 218o, 2182 and 2183 could be used to connect the NAND strings 206 of the sub-block of memory cells 240i to the data lines 2O4o and 204i, and to isolate the NAND strings 206 of the sub-blocks of memory cells 24Oo, 2402 and 240s from the data lines 2O4o and 204i. Furthermore, a control signal of 5V applied to the select line 218o and control signals of 0V applied to the select lines 2181, 2182 and 2183 could be used to connect the NAND strings 206 of the sub-block of memory cells 24Oo to the data lines 2O4o and 204i, and to isolate the NAND strings 206 of the sub-blocks of memory cells 240i, 2402 and 240s from the data lines 2O4o and 204i.

[0071] Selective programming of the select gates 212 might be facilitated by the preconfigured select gates 328. For example, the pre-configured select gates 328 corresponding to each sub-block of memory cells 240 might have a respective binary permutation of two (e.g., high and low) threshold voltages. For example, assigning the high and low threshold voltages as corresponding to binary values 1 and 0, respectively, a set of pre-configured select gates 328o and 328i can have one of four different binary permutations, e.g., 00 (e.g., low-low), 01 (e.g., low-high), 10 (e.g., high-low), and 11 (e.g., high-high). High threshold voltages are indicated by the thick black control gates of the pre-configured select gates 328. In the example of Figure 3C, the pre-configured select gates 328o and 328i corresponding to the sub-block of memory cells 24Oo both have high (e.g., positive) threshold voltages, the preconfigured select gates 328o and 328i corresponding to the sub-block of memory cells 240i have high (e.g., positive) and low (e.g., negative) threshold voltages, respectively, the preconfigured select gates 328o and 328i corresponding to the sub-block of memory cells 2402 have low (e.g., negative) and high (e.g., positive) threshold voltages, respectively, and the pre-configured select gates 328o and 3281 corresponding to the sub-block of memory cells 24(h both have low (e.g., negative) threshold voltages. The binary permutations of two threshold voltages of the pre-configured select gates 328 for each sub-block of memory cells 240 are mutually exclusive, e.g., the binary permutation of two threshold voltages for one sub-block of memory cells 240 of a block of memory cells 242 is different than the binary permutation of two threshold voltages for each remaining sub-block of memory cells 240 of that block of memory cells 242.

[0072] Note that determining a binary permutation of two threshold voltages, as used herein, looks to each transistor individually as to its possible threshold voltages when assigning a binary value to that transistor. Consider the example where the binary value 1 is assigned to the higher of two possible threshold voltages for a transistor, and the binary value 0 is assigned to the lower of two possible threshold voltages for that transistor. If a preconfigured select gate 328o could be assigned a first threshold voltage or a second threshold voltage higher than the first threshold voltage, and a pre-configured select gate 328i could be assigned a third threshold voltage or a fourth threshold voltage higher than the third threshold voltage, the pre-configured select gate 328o would be assigned the binary value 0 if it was assigned the first threshold voltage and would be assigned the binary value 1 if it was assigned the second threshold voltage, and the pre-configured select gate 3281 would be assigned the binary value 0 if it was assigned the third threshold voltage and would be assigned the binary value 1 if it was assigned the fourth threshold voltage, regardless of whether the first threshold voltage and the third threshold voltage were equal, and regardless of whether the second threshold voltage and the fourth threshold voltage were equal. Thus, for a set of transistors, the threshold voltage for each transistor relative to its two possible states (e.g., low or high for that transistor) is controlling in determining the binary permutation of two threshold voltages for that set of transistors, regardless of the actual values of the possible threshold voltages for each of the transistors.

[0073] To program the select gates 212s corresponding to the sub-block of memory cells 240s, the select gates 210 might be deactivated, the GG gates 222 might be activated, and control signals might be applied to the select lines 33Oo and 330i that are configured to activate those pre-configured select gates 328 having the low threshold voltage, and to deactivate those pre-configured select gates 328 having the high threshold voltage. A reference potential, e.g., Vss, ground or 0V, might be applied to the data lines 204. In this manner, the select gates 212s corresponding to the sub-block of memory cells 240s, might be connected to their respective data line 204 and be enabled for programming, while the select gates 212s corresponding to the remaining sub-blocks of memory cells 24Oo, 2401 and 2402 might be isolated from their respective data lines 204 and prohibited from programming by having the channel potential boosted to reduce a potential difference between the select line 2183 and the channel. As such, by applying a programming voltage signal to the select line 2183 sufficient to increase the threshold voltages of the select gates 2123 corresponding to the sub-block of memory cells 2403, and applying voltage signals to remaining select lines 2180, 218i and 2182, as well as to the access lines 2O2O-2O2N, that are configured to inhibit an increase in threshold voltage of the other select gates 212o, 2121 and 2122, and the memory cells 208, the select gates 2123 corresponding to the sub-block of memory cells 2403 might be programmed to have the high threshold voltage without programming other select gates 2123.

[0074] To program the select gates 2122 corresponding to the sub-block of memory cells 2402, the select gates 210 might be deactivated, and the GG gates 222 might be activated. A control signal might be applied to the select line 33Oo that is configured to activate those preconfigured select gates 328 having the low threshold voltage, and to deactivate those preconfigured select gates 328 having the high threshold voltage. A control signal might be applied to the select line 330i that is configured to activate pre-configured select gates 328 having the low threshold voltage and to activate pre-configured select gates 328 having the high threshold voltage. A control signal might be applied to the select line 2183 that is configured to activate those select gates 2123 having the low threshold voltage, and to deactivate those select gates 212s having the high threshold voltage. A reference potential, e.g., Vss, ground or 0V, might be applied to the data lines 204. In this manner, the select gates 2122 corresponding to the sub-block of memory cells 2402, might be connected to their respective data line 204 and be enabled for programming, while the select gates 2122 corresponding to the remaining sub-blocks of memory cells 24Oo, 240i and 240s might be isolated from their respective data lines 204 and prohibited from programming. Note that although the pre-configured select gates 328 corresponding to the sub-block of memory cells 240s would be activated, the deactivation of the select gates 212s corresponding to the subblock of memory cells 240s might serve to isolate their corresponding select gates 2122 from a data line 204. As such, by applying a programming voltage signal to the select line 2182 sufficient to increase the threshold voltages of the select gates 2122 corresponding to the subblock of memory cells 2402, and applying voltage signals to remaining select lines 2180, 2181 and 2183, as well as to the access lines 2O2O-2O2N, that are configured to inhibit an increase in threshold voltage of the other select gates 212o, 212i and 2123, and the memory cells 208, the select gates 2122 corresponding to the sub-block of memory cells 2402 might be programmed to have the high threshold voltage without programming other select gates 2122.

[0075] To program the select gates 212i corresponding to the sub-block of memory cells 240i, the select gates 210 might be deactivated, and the GG gates 222 might be activated. A control signal might be applied to the select line 33Oo that is configured to activate preconfigured select gates 328 having the low threshold voltage and to activate pre-configured select gates 328 having the high threshold voltage. A control signal might be applied to the select line 330i that is configured to activate those pre-configured select gates 328 having the low threshold voltage, and to deactivate those pre-configured select gates 328 having the high threshold voltage. A control signal might be applied to the select lines 2183 and 2182 that are configured to activate those select gates 2123 and 2122, respectively, having the low threshold voltage, and to deactivate those select gates 2123 and 2122, respectively, having the high threshold voltage. A reference potential, e.g., Vss, ground or 0V, might be applied to the data lines 204. In this manner, the select gates 212i corresponding to the sub-block of memory cells 240i, might be connected to their respective data line 204 and be enabled for programming, while the select gates 212i corresponding to the remaining sub-blocks of memory cells 24Oo, 2402 and 2403 might be isolated from their respective data lines 204 and prohibited from programming. Note that although the pre-configured select gates 328 corresponding to the sub-block of memory cells 2403 would both be activated, the deactivation of the select gates 212s corresponding to the sub-block of memory cells 2403 might serve to isolate their corresponding select gates 212i from a data line 204. As such, by applying a programming voltage signal to the select line 218i sufficient to increase the threshold voltages of the select gates 212i corresponding to the sub-block of memory cells 240i, and applying voltage signals to remaining select lines 218o, 2182 and 218s, as well as to the access lines 2O2O-2O2N, that are configured to inhibit an increase in threshold voltage of the other select gates 212o, 2122 and 2123, and the memory cells 208, the select gates 212i corresponding to the sub-block of memory cells 2401 might be programmed to have the high threshold voltage without programming other select gates 212i.

[0076] To program the select gates 212o corresponding to the sub-block of memory cells 24Oo, the select gates 210 might be deactivated, and the GG gates 222 might be activated. A control signal might be applied to the select lines 33Oo and 330i that are configured to activate pre-configured select gates 328 having the low threshold voltage and to activate preconfigured select gates 328 having the high threshold voltage. A control signal might be applied to the select lines 2183, 2182 and 2181 that are configured to activate those select gates 212s, 2122 and 212i, respectively, having the low threshold voltage, and to deactivate those select gates 2123, 2122 and 212i, respectively, having the high threshold voltage. A reference potential, e.g., Vss, ground or 0V, might be applied to the data lines 204. In this manner, the select gates 212o corresponding to the sub-block of memory cells 24Oo, might be connected to their respective data line 204 and be enabled for programming, while the select gates 212o corresponding to the remaining sub-blocks of memory cells 240i, 2402 and 240s might be isolated from their respective data lines 204 and prohibited from programming. Note that although the pre-configured select gates 328 corresponding to the sub-block of memory cells 240s , 2402 and 240i would all be activated, the deactivation of the select gates 212s, 2122 and 212i corresponding to the sub-blocks of memory cells 240s, 2402 and 240i, respectively, might serve to isolate their corresponding select gates 212o from a data line 204. As such, by applying a programming voltage signal to the select line 2180 sufficient to increase the threshold voltages of the select gates 212o corresponding to the sub-block of memory cells 24Oo, and applying voltage signals to remaining select lines 2181, 2182 and 2183, as well as to the access lines 2O2O-2O2N, that are configured to inhibit an increase in threshold voltage of the other select gates 212i, 2122 and 2123, and the memory cells 208, the select gates 212o corresponding to the sub-block of memory cells 24Oo might be programmed to have the high threshold voltage without programming other select gates 212o.

[0077] Figure 4A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1. Like numbered elements in Figure 4A correspond to the description as provided with respect to Figure 3A. Figure 4A depicts an array structure that could be used in cases where a block of memory cells contains two subblocks of memory cells. The structure of Figure 4A further depicts the inclusion of dummy select lines 450 and dummy select lines 460. Dummy select lines 450 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent select line 330. Dummy select lines 460 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent access lines 202. Transistors 408 formed at intersections of a channel material structure 244 and dummy select lines 450 and 460 might utilize a structure similar to (e.g., the same as) the memory cells 208 of Figure 3A. Although various structures referred to in the discussion of Figure 4A and subsequent figures might not be explicitly depicted therein, e.g., pre-configured select gates 328, their location will be apparent in context, and/or by referencing figures in which they were first introduced.

[0078] In Figure 4A, the channel material structures 244o-244i are depicted to be hollow channel material structures. Alternatively, the channel material structures 244o-244i could be solid structures. The channel material structure 244o might belong to a first sub-block of memory cells 24Oo of a block of memory cells, while the channel material structure 244i might belong to a second sub-block of memory cells 240i of that block of memory cells. As such, the pre-configured select gate 328 connected to the select line 330 and formed at an intersection with the channel material structure 244o might have a first threshold voltage, while the pre-configured select gate 328 connected to the select line 330 and formed at an intersection with the channel material structure 244i might have a second threshold voltage different than (e.g., lower than) the first threshold voltage. This might be accomplished by forming a doped section 452 in the channel material structure 244o to increase the threshold voltage of the corresponding transistor (e.g., pre-configured select gate 328) formed at the intersection of the select line 330 with the channel material structure 244o. The doped section 452 might contain an impurity configured to increase a threshold voltage of the corresponding transistor. As an example, the impurity might comprise boron as a dopant material. Although the channel material structures 244o and 244i are depicted to be immediately adjacent one another, there may be intervening channel material structures 244 not connected to the data line 204, as will be depicted in Figure 4D. Similarly, although Figure 4A depicts only two sub-blocks of memory cells 240, a block of memory cells might include other numbers of sub-blocks of memory cells 240.

[0079] Following fabrication, one or more select gates 212 formed at intersections between the channel material structure 244i and the select lines 218io-21812 might be programmed (indicated with the label “P” at the intersection) to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. Subsequently, one or more select gates 212 formed at intersections between the channel material structure 244o and the select lines 218oo-218o2 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. Table 1 presents voltages for various nodes of Figure 4 A during the two stages of programming.

Table 1

[0080] It is noted that voltages to be applied to dummy select lines 460 as well as other nodes between the dummy select lines 460 and a common source, e.g., access lines 202, dummy access lines, select lines 214, control lines 224, etc., might take any approach configured to inhibit programming of those transistors. For example, all of these nodes could receive the pass voltage VPASS to inhibit program disturb of corresponding transistors connected to the data line 204. Alternatively, the dummy select lines 460 could receive a gradient of voltage levels configured to inhibit program disturb of corresponding transistors closest to the select lines 218, while cutting off transistors (e.g., memory cells) corresponding to the access lines 202 from the data line 204 to inhibit their programming.

[0081] As depicted in Table 1, the data line 204 might receive an enable voltage VEN configured to enable programming of a programmable transistor connected to the data line. As one example, the enable voltage VEN might be a reference potential, e.g., 0V, ground or Vss. The SGD_GG control line 226 might receive a pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select line 330 might receive a first voltage level VSGP_LOW configured to deactivate pre-configured select gate 328 having the first threshold voltage, and to activate pre-configured select gate 328 having the second threshold voltage lower than the first threshold voltage. As such, the first voltage level VSGP_LOW might activate pre-configured select gate 328 at the intersection of the select line 330 and the channel material structure 244i, and deactivate pre-configured select gate 328 at the intersection of the select line 330 and the channel material structure 244o. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. In this manner, select gates 212 at intersections of the select lines 218 and the channel material structure 244i might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218 and the channel material structure 244o might be isolated from the data line 204 and inhibited from programming. As such, upon application of a programming voltage VPGM (e.g., a voltage level configured to increase a threshold voltage of a programmable transistor enabled for programming) to the select lines 218io-218i2, those transistors corresponding to the channel material structure 244i might be programmed to have a higher threshold voltage, while those transistors corresponding to the channel material structure 244o might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0082] Following the programming of the select gates 212 corresponding to the select lines 218io-218i2, select gates 212 corresponding to the select lines 218oo-218o2 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select line 330 might receive the pass voltage VPASS configured to activate all of its corresponding pre-configured select gates 328, regardless of their threshold voltages. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 218io-218i2 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 218oo- 218O2 and the channel material structure 244o might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218oo- 218O2 and the channel material structure 2441 might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 218oo-218o2, those transistors corresponding to the channel material structure

2440 might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structure 2441 might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0083] As one example, the first threshold voltage of the pre-configured select gates 328 might be 3V while the second threshold voltage of the pre-configured select gates 328 might be -IV. To continue the example, the programmed threshold voltage of the select gates 212 might be 4V and the initial threshold voltage might be -IV. In this example, VSGP_LOW and VSGD LOW might be IV, VPASS might be 7V, and VPGM might be 18V. Alternatively, all select gates 212 at the intersections of the select lines 218 and the channel material structures 244o-

2441 might be programmed to a positive threshold voltage, e.g., 2V, as their initial threshold voltage prior to programming of the select gates 212 by sub-blocks of memory cells as described. In such an embodiment, VSGD LOW might be increased to 3V, for example.

[0084] Programming of select gates 212 might utilize an iterative process of applying a programming pulse to a programmable transistor and verifying if that transistor has reached a desired threshold voltage in response to that programming pulse, and repeating that iterative process until that transistor passes the verification. Alternatively, programming of select gates 212 might utilize a single programming pulse having a voltage level configured to increase the threshold voltage above some particular voltage level, e.g., above a voltage level to be used to activate an unprogrammed select gate 212 and deactivate a programmed select gate 212. A voltage level of a programming pulse sufficient to increase the threshold voltage of any select gate 212 above the particular voltage level might, for example, be determined experimentally, empirically or through simulation. When programming using an iterative process, select gates 212 might be programmed sequentially as is typical, e.g., applying increasing programming voltage levels to select line 21810 until passing a verify operation, then applying increasing programming voltage levels to select line 218n until passing a verify operation, then applying increasing programming voltage levels to select line 21812 until passing a verify operation. Alternatively, programming select gates 212 using an iterative process might be performed concurrently, e.g., applying increasing programming voltage levels to select lines 218io, 218n, and 21812 concurrently until passing a verify operation while a verify voltage is applied to each of the select lines 218io, 21811, and 21812, indicating that each of the select gates 212 has a threshold voltage above the verify voltage.

[0085] Figures 4B-4C depict representations of top views of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 4A. Figure 4B might depict a block of memory cells containing two sub-blocks of memory cells 240, e.g., sub-blocks of memory cells 24Oo-24Oi, where the two sub-blocks of memory cells 24Oo-24Oi might use a structure of a type similar to that depicted in Figure 4A. Figure 4B might depict a distribution of channel material structures 244 throughout the select line 330. In Figure 4B, each channel material structure 244 of the sub-block of memory cells 24Oo might contain a respective doped section 452 as depicted in Figure 4A.

[0086] Figure 4C might depict a block of memory cells containing four sub-blocks of memory cells 240, e.g., sub-blocks of memory cells 24Ooo-24Ooi and 24Oio-24On, where the two sub-blocks of memory cells 24Ooo-24Ooi might use a structure of a type similar to that depicted in Figure 4A and the two sub-blocks of memory cells 24Oio-24On might use a structure of a type similar to that depicted in Figure 4A, but the two sub-blocks of memory cells 24Ooo-24Ooi are separated, e.g., by dielectric, from the two sub-blocks of memory cells 24010-24011. Figure 4C might further depict a distribution of channel material structures 244 throughout the select lines 330. In Figure 4C, each channel material structure 244 of the subblock of memory cells 24Ooo and each channel material structure 244 of the sub-block of memory cells 24Ooi might contain a respective doped section 452 as depicted in Figure 4A.

[0087] Figure 4D depicts a conceptualized representation of a top view of two sub-blocks of memory cells of an array of memory cells including a structure of a type similar to that depicted in Figure 4A and depicting an orientation of data lines 204. With reference to Figure 4A, the channel material structures 244 connected to the data line 2O4o through their respective contacts 458 might correspond to the channel material structures 244o and 244i of Figure 4A. Although there is an intervening channel material structure 244 depicted that is part of the sub-block of memory cells 24Oo, it is not connected to the data line 2O4o, but instead connected to the data line 204i. In general, each sub-block of memory cells 240 might have only one channel material structure 244 connected to any one data line 204.

[0088] Figure 5 A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1. Like numbered elements in Figure 5 A correspond to the description as provided with respect to Figure 4A. Figure 5 A depicts an array structure that could be used in cases where a block of memory cells contains four subblocks of memory cells. In the example of Figure 5 A, multiple select lines 330, e.g., select lines 33Oo-33Oi, might be used in the programming the select lines 218. The structure of Figure 5 A further depicts the inclusion of dummy select lines 450 and dummy select lines 460. Dummy select lines 450 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent select line 330. Dummy select lines 460 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent access lines 202.

[0089] In Figure 5A, the channel material structures 244o-244s are depicted to be hollow channel material structures. Alternatively, the channel material structures 244o-244s could be solid structures (not depicted in Figure 5A). The channel material structure 244o might belong to a first sub-block of memory cells 24Oo of a block of memory cells, the channel material structure 244i might belong to a second sub-block of memory cells 240i of that block of memory cells, the channel material structure 2442 might belong to a third sub-block of memory cells 2402 of that block of memory cells, and the channel material structure 244s might belong to a fourth sub-block of memory cells 240s of that block of memory cells. As such, the pre-configured select gates 328 connected to the select line 33Oo and formed at intersections with the channel material structures 244o-244i might have a first threshold voltage, while the pre-configured select gates 328 connected to the select line 33Oo and formed at intersections with the channel material structures 2442-2443 might have a second threshold voltage different than (e.g., lower than) the first threshold voltage. In addition, the pre-configured select gates 328 connected to the select line 330i and formed at intersections with the channel material structures 244o and 2442 might have the first threshold voltage, while the pre-configured select gates 328 connected to the select line 330i and formed at intersections with the channel material structures 244i and 244s might have the second threshold voltage. This might be accomplished by forming first doped sections 452 in the channel material structures 244o-244i to increase the threshold voltages of the corresponding transistors (e.g., pre-configured select gates 328) formed at intersections of the select line 33Oo with the channel material structures 244o-244i, and by forming second doped sections 454 in the channel material structures 244o and 2442 to increase the threshold voltages of the corresponding transistors (e.g., pre-configured select gates 328) formed at intersections of the select line 330i with the channel material structures 244o and 2442. Although the channel material structures 244o-244s are depicted to be immediately adjacent one another, there may be intervening channel material structures 244 not connected to the data line 204.

[0090] Note that the selection of which channel material structures 244 receive a first doped section 452 and which channel material structures 244 receive a second doped section 454 can be altered. In general, each channel material structure 244 belonging to a particular sub-block of memory cells 240 should have a same configuration of threshold voltages of its pre-configured select gates 328. For example, a pre-configured select gate 328 having the first threshold voltage might be considered as a logical 1, and a pre-configured select gate 328 having the second threshold voltage might be considered as a logical 0. As such, the preconfigured select gates 328 corresponding to a same sub-block of memory cells 240 might correspond to a respective binary permutation of the possible binary permutations of two threshold voltages, e.g., 00, 01, 10 and 11 in the example of Figure 5A having two select lines 330, where 0 represents the lower threshold voltage and 1 represents the higher threshold voltage. Their arrangement among the sub-blocks of memory cells 240 might otherwise be irrelevant.

[0091] Following fabrication, one or more select gates 212 formed at intersections of the channel material structure 244s and the select lines 2I830-2I832 might be programmed (indicated with the label “P” at the intersection) to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage as a first stage of programming the select gates 212. In a second stage of programming, one or more select gates 212 formed at intersections of the channel material structure 2442 and the select lines 2I820-2I822 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a third stage of programming, one or more select gates 212 formed at intersections between the channel material structure 2441 and the select lines 218io-21812 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a fourth stage of programming, one or more select gates 212 (not depicted in Figure 5 A) formed at intersections between the channel material structure 244o and the select lines 218oo-218o2 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. Table 2 presents voltages for various nodes of Figure 5 A during the four stages of programming.

Table 2

[0092] It is noted that voltages to be applied to dummy select lines 460 as well as other nodes between the select lines 218 receiving the programming voltage VPGM and a common source, e.g., access lines 202, dummy access lines, select lines 214, control lines 224, other select lines 218, etc., might take any approach configured to inhibit programming of their corresponding transistors. For example, all of these nodes could receive the pass voltage VPASS to inhibit program disturb of corresponding transistors connected to the data line 204. Alternatively, these nodes could receive a gradient of voltage levels configured to inhibit program disturb of corresponding transistors closest to the select lines 218 receiving the programming voltage VPGM, while cutting off transistors (e.g., memory cells) corresponding to the access lines 202 from the data line 204 to inhibit their programming.

[0093] As depicted in Table 2, for the first stage of programming, the data line 204 might receive an enable voltage VEN configured to enable programming of a programmable transistor connected to the data line. As one example, the enable voltage VEN might be a reference potential, e.g., 0V, ground or Vss. The SGD_GG control line 226 might receive a pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo and 330i might each receive a first voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the first voltage level VSGP_LOW might activate preconfigured select gates 328 at intersections of the select line 330i and the channel material structures 244i and 244s. and deactivate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o and 2442. Similarly, the first voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 2442 and 244s. and deactivate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o and 244i. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. In this manner, select gates 212 at intersections of the select lines 218 and the channel material structure 244s might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218 and the channel material structures 244o-2442 might be isolated from the data line 204 and inhibited from programming. As such, upon application of a programming voltage VPGM (e.g., a voltage level configured to increase a threshold voltage of a programmable transistor enabled for programming) to the select lines 21830- 21832, the transistor corresponding to the channel material structure 2443 might be programmed to have a higher threshold voltage, while those transistors corresponding to the channel material structures 244o-2442 might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0094] Following the programming of the select gates 212 corresponding to the select lines 2I830-2I832, the select gates 212 corresponding to the select lines 2I820-2I822 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select line 330i might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage and to activate pre-configured select gates 328 having the second threshold voltage, while the select line 33Oo might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate preconfigured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o-244s. Similarly, the first voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 2442 and 244s, and deactivate preconfigured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o and 244i. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 21830-21832 might receive a voltage VSGD LOW configured to deactivate the select gates 212 corresponding to the channel material structure 2443 (e.g., having the higher threshold voltage) and to activate the select gates 212 corresponding to the channel material structures 244o-2442 (e.g., having the lower threshold voltage). In this manner, select gates 212 at intersections of the select lines 21820-21822 and the channel material structure 2442 might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 2I820-2I822 and the channel material structures 244o, 244i and 2443 might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 21820-21822, those transistors corresponding to the channel material structure 2442 might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o, 2441 and 2443 might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0095] Following the programming of the select gates 212 corresponding to the select lines 2I820-2I822, the select gates 212 corresponding to the select lines 218io-21812 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select line 330i might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage, while the select line 33Oo might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage and to activate pre-configured select gates 328 having the second threshold voltage. As such, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244i and 244s, and deactivate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o and 2442. Similarly, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o-244s. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 21830-21832 and 21820-21822 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage). In this manner, select gates 212 at intersections of the select lines 21810- 21812 and the channel material structure 2441 might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 21810- 21812 and the channel material structures 244o, 2442 and 2443 might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 218io-218i2, those transistors corresponding to the channel material structure 244i might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o, 2442 and 2443 might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0096] Following the programming of the select gates 212 corresponding to the select lines 218io-218i2, the select gates 212 corresponding to the select lines 218oo-218o2 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo and 330i might each receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage and to activate pre-configured select gates 328 having the second threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select lines 33Oo and 330i, and the channel material structures 244o-244s. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 21830-21832, 2I820-2I822 and 218io-218i2 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 21800- 21802 and the channel material structure 244o might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 21800- 21802 and the channel material structures 2442 and 2443 might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 218oo-218o2, those transistors corresponding to the channel material structure 244o might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 2441-2443 might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0097] As one example, the first threshold voltage of the pre-configured select gates 328 might be 3V while the second threshold voltage of the pre-configured select gates 328 might be -IV. To continue the example, the programmed threshold voltage of the select gates 212 might be 4V and the initial threshold voltage might be -IV. In this example, VSGP_LOW and VSGD LOW might be IV, VPASS might be 7V, and VPGM might be 18V. Alternatively, all select gates 212 at the intersections of the select lines 218 and the channel material structures 244o- 2443 might be programmed to a positive threshold voltage, e.g., 2V, as their initial threshold voltage prior to programming of the select gates 212 by sub-blocks of memory cells as described. In such an embodiment, VSGD LOW might be increased to 3V, for example.

[0098] Figure 5B depicts a representation of a top view of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 5A. Figure 5B might depict a distribution of channel material structures 244 throughout the select line 330x, where select line 330x might represent any one of the select lines 33Oo or 330i. In Figure 5B, each channel material structure 244 of the sub-blocks of memory cells 24Oo and 240i might contain a respective doped section 452 as depicted in Figure 5A, and each channel material structure 244 of the sub-blocks of memory cells 24Oo and 2402 might contain a respective doped section 454 as depicted in Figure 5A.

[0099] Figure 6A depicts a conceptualized representation of a cross-sectional view of a portion of an array structure in accordance with an embodiment as could be used in a memory of the type described with reference to Figure 1. Like numbered elements in Figure 6A correspond to the description as provided with respect to Figure 4A. Figure 6A depicts an array structure that could be used in cases where a block of memory cells contains eight subblocks of memory cells. In the example of Figure 6A, multiple select lines 330, e.g., select lines 33Oo-33O2, might be used in the programming the select lines 218. The structure of Figure 6A further depicts the inclusion of dummy select lines 450 and dummy select lines 460. Dummy select lines 450 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent select line 330. Dummy select lines 460 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent access lines 202.

[0100] In Figure 6A, the channel material structures 244o-244? are depicted to be solid channel material structures. Alternatively, the channel material structures 244o-244s could be hollow structures (not depicted in Figure 6A). The channel material structure 244o might belong to a first sub-block of memory cells 24Oo of a block of memory cells, the channel material structure 244i might belong to a second sub-block of memory cells 240i of that block of memory cells, the channel material structure 2442 might belong to a third sub-block of memory cells 2402 of that block of memory cells, the channel material structure 244s might belong to a fourth sub-block of memory cells 240s of that block of memory cells, the channel material structure 2444 might belong to a fifth sub-block of memory cells 2404 of that block of memory cells, the channel material structure 244s might belong to a sixth sub-block of memory cells 240s of that block of memory cells, the channel material structure 244e might belong to a seventh sub-block of memory cells 240e of that block of memory cells, and the channel material structure 244? might belong to an eighth sub-block of memory cells 240? of that block of memory cells.

[0101] As such, the pre-configured select gates 328 connected to the select line 33Oo and formed at intersections with the channel material structures 244o, 244i, 2444 and 244s might have a first threshold voltage, while the pre-configured select gates 328 connected to the select line 33Oo and formed at intersections with the channel material structures 2442, 244s. 2446 and 244? might have a second threshold voltage different than (e.g., lower than) the first threshold voltage. In addition, the pre-configured select gates 328 connected to the select line 330i and formed at intersections with the channel material structures 244o, 2442, 2444 and 2446 might have a first threshold voltage, while the pre-configured select gates 328 connected to the select line 330i and formed at intersections with the channel material structures 244i,

2441. 244s and 244? might have a second threshold voltage different than (e.g., lower than) the first threshold voltage. Furthermore, the pre-configured select gates 328 connected to the select line 3302 and formed at intersections with the channel material structures 244o, 244i, 2442 and 244s might have a first threshold voltage, while the pre-configured select gates 328 connected to the select line 3302 and formed at intersections with the channel material structures 2444, 244s, 244e and 244? might have a second threshold voltage different than (e.g., lower than) the first threshold voltage. This might be accomplished by forming first doped sections 452 in the channel material structures 244o, 244i, 2444 and 244s to increase the threshold voltages of the corresponding transistors (e.g., pre-configured select gates 328) formed at intersections of the select line 33Oo with the channel material structures 244o, 244i, 2444 and 244s, by forming second doped sections 454 in the channel material structures 244o,

2442, 2444 and 244e to increase the threshold voltages of the corresponding transistors (e.g., pre-configured select gates 328) formed at intersections of the select line 330i with the channel material structures 244o, 2442, 2444 and 2446, and by forming third doped sections 456 in the channel material structures 244o, 244i, 2442 and 244s to increase the threshold voltages of the corresponding transistors (e.g., pre-configured select gates 328) formed at intersections of the select line 3302 with the channel material structures 244o, 244i, 2442 and 244s. Although the channel material structures 244o-244? are depicted to be immediately adjacent one another, there may be intervening channel material structures 244 not connected to the data line 204.

[0102] Note that the selection of which channel material structures 244 receive a first doped section 452, which channel material structures 244 receive a second doped section 454, and which channel material structures 244 receive a third doped section 456 can be altered. In general, each channel material structure 244 belonging to a particular sub-block of memory cells 240 should have a same configuration of threshold voltages of its preconfigured select gates 328. For example, a pre-configured select gate 328 having the first threshold voltage might be considered as a logical 1, and a pre-configured select gate 328 having the second threshold voltage might be considered as a logical 0. As such, the preconfigured select gates 328 corresponding to a same sub-block of memory cells 240 might correspond to a respective binary permutation of the possible binary permutations of two threshold voltages, e.g., 000 (e.g., low-low-low), 001 (e.g., low-low-high), 010 (e.g., low- high-low), 011 (e.g., low-high-high), 100 (e.g., high-low-low), 101 (e.g., high-low-high), 110 (e.g., high-high-low), and 111 (e.g., high-high-high) in the example of Figure 6A having three select lines 330, where 0 represents the lower threshold voltage and 1 represents the higher threshold voltage. Their arrangement among the sub-blocks of memory cells 240 might otherwise be irrelevant.

[0103] Following fabrication, one or more select gates 212 formed at intersections between the channel material structure 244? and the select lines 2I870-2I871 might be programmed (indicated with the label “P” at the intersection) to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage as a first stage of programming the select gates 212. In a second stage of programming, one or more select gates 212 formed at intersections between the channel material structure 244e and the select lines 21860-21861 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a third stage of programming, one or more select gates 212 formed at intersections between the channel material structure 244s and the select lines 21850-21851 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a fourth stage of programming, one or more select gates 212 formed at intersections between the channel material structure 2444 and the select lines 21840-21841 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a fifth stage of programming, one or more select gates 212 formed at intersections between the channel material structure 244s and the select lines 21830-21831 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a sixth stage of programming, one or more select gates 212 formed at intersections between the channel material structure 2442 and the select lines 2I820-2I821 might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In a seventh stage of programming, one or more select gates 212 formed at intersections between the channel material structure 244i and the select lines 218io-218n might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. In an eighth stage of programming, one or more select gates 212 (not depicted in Figure 6A) formed at intersections between the channel material structure 244o and the select lines 218oo-218oi might be programmed to have a programmed threshold voltage higher than an initial (e.g., erased) threshold voltage. Table 3 presents voltages for various nodes of Figure 6A during the four stages of programming.

Table 3

[0104] It is noted that voltages to be applied to dummy select lines 460 as well as other nodes between the select lines 218 receiving the programming voltage VPGM and a common source, e.g., access lines 202, dummy access lines, select lines 214, control lines 224, other select lines 218, etc., might take any approach configured to inhibit programming of their corresponding transistors. For example, all of these nodes could receive the pass voltage VPASS to inhibit program disturb of corresponding transistors connected to the data line 204. Alternatively, these nodes could receive a gradient of voltage levels configured to inhibit program disturb of corresponding transistors closest to the select lines 218 receiving the programming voltage VPGM, while cutting off transistors (e.g., memory cells) corresponding to the access lines 202 from the data line 204 to inhibit their programming.

[0105] As depicted in Table 3, for the first stage of programming, the data line 204 might receive an enable voltage VEN configured to enable programming of a programmable transistor connected to the data line. As one example, the enable voltage VEN might be a reference potential, e.g., 0V, ground or Vss. The SGD_GG control line 226 might receive a pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo, 330i and 3302 might each receive a first voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the first voltage level VSGP_LOW might activate preconfigured select gates 328 at intersections of the select line 3302 and the channel material structures 2444-244?, and deactivate pre-configured select gates 328 at intersections of the select line 33012 and the channel material structures 244o-2443. Similarly, the first voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244i, 244s. 244s and 244?, and deactivate preconfigured select gates 328 at intersections of the select line 330i and the channel material structures 244o, 2442, 2444 and 244e. Furthermore, the first voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 2442, 244s, 244e and 244?, and deactivate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o, 244i, 2444 and 244s. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors.

[0106] In this manner, select gates 212 at intersections of the select lines 218 and the channel material structure 244? might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218 and the channel material structures 244o-244e might be isolated from the data line 204 and inhibited from programming. As such, upon application of a programming voltage VPGM (e.g., a voltage level configured to increase a threshold voltage of a programmable transistor enabled for programming) to the select lines 21870-21871, the transistors corresponding to the channel material structure 2447 might be programmed to have a higher threshold voltage, while those transistors corresponding to the channel material structures 244o-244e might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0107] Following the programming of the select gates 212 corresponding to the select lines 2I870-2I871, the select gates 212 corresponding to the select lines 21860-21861 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo and 3302 might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage, and select line 330i might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o-2447. Similarly, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 2442, 244s, 244e and 2447, and deactivate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o, 244i, 2444 and 244s. Furthermore, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 3302 and the channel material structures 2444-244?, and deactivate pre-configured select gates 328 at intersections of the select line 3302 and the channel material structures 244o-2443. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 2I870-2I871 might receive a voltage level VSGD LOW configured to deactivate the select gates 212 corresponding to the channel material structure 244? having the higher threshold voltage, and to activate the select gates 212 corresponding to the channel material structures 244o- 2446 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 21860-21861 and the channel material structure 244e might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 21860-21861 and the channel material structures 244o-2445 and 244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 21860-21861, those transistors corresponding to the channel material structure 244e might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244O-2445 and 244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0108] Following the programming of the select gates 212 corresponding to the select lines 21860-21861, the select gates 212 corresponding to the select lines 21850-21851 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 330i and 330? might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage, while the select line 33Oo might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage. As such, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33(h and the channel material structures 2444-244?, and deactivate pre-configured select gates 328 at intersections of the select line 3302 and the channel material structures 244o-244s. Similarly, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244i, 244?. 244s and 244?, and deactivate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o, 2442, 2444 and 2446. Furthermore, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o-244?. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 2I870-2I871 and 21860-21861 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 218so-21851 and the channel material structure 244s might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218so-21851 and the channel material structures 244o-2444, 244e, and 244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 2I850-2I851, those transistors corresponding to the channel material structure 244s might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244O-2444, 244e, and 244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0109] Following the programming of the select gates 212 corresponding to the select lines 2I850-2I851, the select gates 212 corresponding to the select lines 21840-21841 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo and 330i might each receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage, and the select line 3302 might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select lines 33Oo and 330i, and the channel material structures 244o-2447. Similarly, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 3302 and the channel material structures 2444-2447, and deactivate pre-configured select gates 328 at intersections of the select line 3302 and the channel material structures 244o-2443. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 21870-21871, 21860-21861 and 218so-21851 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 21840-21841 and the channel material structure 2444 might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 21840-21841 and the channel material structures 244o-244s and 2445-244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 21840-21841, those transistors corresponding to the channel material structure 2444 might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o-244s and 2445-244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0110] Following the programming of the select gates 212 corresponding to the select lines 21840-21841, the select gates 212 corresponding to the select lines 21830-21831 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select line 330? might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage, and the select lines 33Oo and 330i might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select line 33(h and the channel material structures 244o-244?. Similarly, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244i, 244s, 244s and 244?, and deactivate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244o, 244 . 2444 and 2446. Furthermore, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244?. 244?. 244e and 244?, and deactivate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o, 244i, 2444 and 244s. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 218?o-2187i, 21860-21861, 218so-21851 and 21840-21841 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 21830-21831 and the channel material structure 2444 might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 21830-21831 and the channel material structures 244o-2442 and 2444-244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 21830-21831, those transistors corresponding to the channel material structure 2443 might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o-2442 and 2444-244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0111] Following the programming of the select gates 212 corresponding to the select lines 2I830-2I831, the select gates 212 corresponding to the select lines 2I820-2I821 might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 330i and 3302 might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage, and the select line 33Oo might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select lines 330i and 33(h, and the channel material structures 244o-244?. Similarly, the voltage level VSGP_LOW might deactivate pre-configured select gates 328 at intersections of the select line 33Oo and the channel material structures 244o, 244i, 2444 and 244s, and activate preconfigured select gates 328 at intersections of the select line 33Oo and the channel material structures 2442, 2443, 244e and 244?. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 2I870-2I871, 21860-21861, 2I850-2I851, 21840-21841 and 2I830-2I831 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 21820-21821 and the channel material structure 2442 might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 2I820-2I821 and the channel material structures 244o, 244i and 2443-244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 2I820-2I821, those transistors corresponding to the channel material structure 2444 might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o, 244i and 2443-244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0112] Following the programming of the select gates 212 corresponding to the select lines 2I820-2I821, the select gates 212 corresponding to the select lines 218io-218n might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo and 3302 might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage, and the select line 330i might receive the voltage level VSGP_LOW configured to deactivate pre-configured select gates 328 having the first threshold voltage, and to activate pre-configured select gates 328 having the second threshold voltage lower than the first threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select lines 33Oo and 33(h, and the channel material structures 244o-244?. Similarly, the voltage level VSGP_LOW might activate pre-configured select gates 328 at intersections of the select line 330i and the channel material structures 244i, 2443, 244s and 244?, and deactivate preconfigured select gates 328 at intersections of the select line 330i and the channel material structures 244o, 2442, 2444 and 244e. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 2I870-2I871, 21860-21861, 21850-21851 , 21840-21841, 21830-21831 and 2I820-2I821 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 218io-21811 and the channel material structure 244i might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218io-218n and the channel material structures 244o and 2442-244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 218io-218n, those transistors corresponding to the channel material structure 244i might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 244o and 2442-244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0113] Following the programming of the select gates 212 corresponding to the select lines 218io-218n, the select gates 212 corresponding to the select lines 218oo-218oi might be programmed. In particular, the data line 204 might receive the enable voltage VEN. The SGD_GG control line 226 might receive the pass voltage VPASS configured to activate its corresponding transistors, e.g., the GG gates 222. The select lines 33Oo-33O2 might receive the pass voltage VPASS configured to activate pre-configured select gates 328 having the first threshold voltage or the second threshold voltage. As such, the pass voltage VPASS might activate pre-configured select gates 328 at intersections of the select lines 33Oo-33O2 and the channel material structures 244o-244?. The dummy select line 450 might receive the pass voltage VPASS configured to activate all of its corresponding transistors. The select lines 218?o-218?i, 21860-21861, 21850-21851 , 21840-21841, 2I830-2I831, 2I820-2I821 and 218io-21811 might receive a voltage VSGD LOW configured to deactivate the select gates 212 having the higher threshold voltage and to activate the select gates 212 having the lower threshold voltage. In this manner, select gates 212 at intersections of the select lines 218oo-218oi and the channel material structure 244o might be connected to the data line 204 and enabled for programming, while the select gates 212 at intersections of the select lines 218oo-218oi and the channel material structures 2441-244? might be isolated from the data line 204 and inhibited from programming. As such, upon application of the programming voltage VPGM to the select lines 218oo-218oi, those transistors corresponding to the channel material structure 244o might be programmed to have the higher threshold voltage, while those transistors corresponding to the channel material structures 2441-244? might be inhibited from programming and remain at their initial, e.g., erased, threshold voltage.

[0114] As one example, the first threshold voltage of the pre-configured select gates 328 might be 3V while the second threshold voltage of the pre-configured select gates 328 might be -IV. To continue the example, the programmed threshold voltage of the select gates 212 might be 4V and the initial threshold voltage might be -IV. In this example, VSGP_LOW and VSGD LOW might be IV, VPASS might be 7V, and VPGM might be 18V. Alternatively, all select gates 212 at the intersections of the select lines 218 and the channel material structures 244o- 244s might be programmed to a positive threshold voltage, e.g., 2V, as their initial threshold voltage prior to programming of the select gates 212 by sub-blocks of memory cells as described. In such an embodiment, VSGD LOW might be increased to 3 V, for example.

[0115] Figure 6B depicts a representation of a top view of a section of an array of memory cells including a structure of a type similar to that depicted in Figure 6A. Figure 6B might depict a distribution of channel material structures 244 throughout the select lines 330, where select line 330x might represent any one of the select lines 33Oo-33O2. In Figure 6B, each channel material structure 244 of the sub-blocks of memory cells 24Oo, 240i, 2404 and 2405 might contain a respective doped section 452 as depicted in Figure 6 A, each channel material structure 244 of the sub-blocks of memory cells 24Oo, 2402, 2404 and 240e might contain a respective doped section 454 as depicted in Figure 6A, and each channel material structure 244 of the sub-blocks of memory cells 24Oo-24O3 might contain a respective doped section 456 as depicted in Figure 6A.

[0116] Figures 7A-7F depict conceptualized representations of cross-sectional views of portions of an array structure in accordance with additional embodiments as could be used in a memory of the type described with reference to Figure 1. Like numbered elements in Figures 7A-7F correspond to the description as provided with respect to Figure 4A. Figure 7 A depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7A differs from the structure of Figure 5A by depicting solid channel material structures 244, and the further inclusion of dummy select lines 462 located between the select lines 218 corresponding to each of the sub-blocks of memory cells 240. Programming of select gates 212 might proceed in a manner similar to that discussed with reference to Figure 5A. Dummy select lines 462 could be used in any embodiment to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218 corresponding to one sub-block of memory cells 240 (e.g., select lines 2I830-2I832 corresponding to the sub-block of memory cells 240s), and the transistors connected to select lines 218 corresponding to an adjacent subblock of memory cells 240 (e.g., select lines 21820-21822 corresponding to the sub-block of memory cells 2402). Transistors 408 formed at intersections of a dummy select line 462 and a channel material structure 244 might utilize a structure similar to (e.g., the same as) the memory cells 208 of Figure 3 A.

[0117] Figure 7B depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7B differs from the structure of Figure 5 A by depicting solid channel material structures 244, and the further inclusion of redundant select lines 330. Programming of select gates 212 might proceed in a manner similar to that discussed with reference to Figure 5 A, where voltage levels applied to select line 33Oo in Figure 5 A would be applied to select lines 33Ooo and 33Ooi in Figure 7B, and where voltage levels applied to select line 330i in Figure 5 A would be applied to select lines 33Oio and 330n in Figure 7B. Redundant select lines 330 might be used to increase levels of cut-off while inhibiting programming for some channel material structures 244. In addition, redundant select lines 330 might mitigate any failure rates resulting from inaccurate placement of the doped sections 452 or 454 in the channel material structure 244 for a given pre-configured select gate 328. For example, even if only one of the pre-configured select gates 328 formed at the intersections of the select lines 33Ooo and 33Ooi and the channel material structures 244o and 244i has the doped section 452 placed in the body of those pre-configured select gates 328, programming of the select gates 212 might still be possible.

[0118] In Figure 7B, pre-configured select gates 328 formed at intersections of a particular channel material structure 244 and the select lines 33Ooo, 33Ooi, 33Oio and 330n might be thought of as a first set of field-effect transistors formed at intersections of the particular channel material structure 244 and the select lines 33Ooo and 33Oio, and a second set of field-effect transistors formed at intersections of the particular channel material structure 244 and the select lines 33Ooi and 330n, with both being fabricated to have a same binary permutation of two threshold voltages. The first set of field-effect transistors and the second set of field-effect transistors might be interleaved, as depicted in Figure 7B.

[0119] Figure 7C depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7C differs from the structure of Figure 7B by depicting redundant select lines 330 for only one of the doped sections. Programming of select gates 212 might proceed in a manner similar to that discussed with reference to Figure 5A, where voltage levels applied to select line 33Oo in Figure 5A would be applied to select lines 33Ooo and 33Ooi in Figure 7C, and where voltage levels applied to select line 330i in Figure 5 A would be applied to select line 33Oio in Figure 7C. Redundant select lines 330 might be used to increase levels of cut-off while inhibiting programming for some channel material structures 244. In addition, redundant select lines 330 might mitigate any failure rates resulting from inaccurate placement of the doped sections 452 or 454 in the channel material structure 244 for a given pre-configured select gate 328. For example, even if only one of the pre-configured select gates 328 formed at the intersections of the select lines 33Ooo and 33Ooi and the channel material structures 244o and 244i has the doped section 452 placed in the body of those pre-configured select gates 328, programming of the select gates 212 might still be possible.

[0120] In Figure 7C, pre-configured select gates 328 formed at intersections of a particular channel material structure 244 and the select lines 33Ooo, 33Ooi and 33Oio might be thought of as a first set of field-effect transistors formed at intersections of the particular channel material structure 244 and the select lines 33Ooo and 33Oio, and a second set of fieldeffect transistors formed at an intersection of the particular channel material structure 244 and the select line 33Ooi, with the second set of field-effect transistors being fabricated to have a same relative threshold voltage as one of the field-effect transistors of the first set of fieldeffect transistors, e.g., the pre-configured select gate 328 formed at the intersection of the particular channel material structure 244 and the select line 33Ooo. The first set of field-effect transistors and the second set of field-effect transistors might be interleaved, as depicted in Figure 7C.

[0121] Figure 7D depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7D differs from the structure of Figure 5 A by depicting solid channel material structures 244, and the further inclusion of varied spacing around select lines 330. Programming of select gates 212 might proceed in a manner similar to that discussed with reference to Figure 5A. Figure 7D depicts a distance dl between the select lines 33Oo and 330i, and a distance d2 between the select line 33Oo and the dummy select line 450. Spacing among other select lines, control lines and access lines might have a distance, e.g., distance d3, that is less than the distance dl and/or less than the distance d2. While the distance dl might equal the distance d2, they could be different. As doped sections are formed deeper in the channel material structures 244, their variability might increase. As such, increased spacing might mitigate failure rates resulting from the extension of a doped section 452 and/or 454 to an unintended transistor body.

[0122] Figure 7E depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7E differs from the structure of Figure 5A by depicting solid channel material structures 244, the further inclusion of doped sections 762 and 764, and the elimination of the GG gates 222 and their control line 226. The doped sections 762 might have a lower concentration of an impurity than the doped sections 452, and the doped sections 764 might have a lower concentration of an impurity than the doped sections 454. In this manner, pre-configured select gates 328 having a doped section 762 might have a lower threshold voltage than pre-configured select gates 328 having a doped section 452, but might also have a positive threshold voltage. Similarly, pre-configured select gates 328 having a doped section 764 might have a lower threshold voltage than pre-configured select gates 328 having a doped section 454, but might also have a positive threshold voltage. As such, the pre-configured select gates 328 might provide the functionality of a GG gate 222, particularly during erase operations. The doped sections 762 and 764 might be formed in a manner similar to that described with reference to the doped sections 452 and 454, respectively, but with complementary masks to expose the appropriate channel material structures 244 for doping. The doped sections 762 and 764 might have different, e.g., lower, impurity levels than the doped sections 452 and 454, respectively. For example, the doped sections 452 or 454 might have an impurity concentration of 2E19/cm ^A 3, while the doped sections 762 or 764 might have an impurity concentration of lE19/cm ^A 3.

[0123] Figure 7F depicts an array structure that could be used in cases where a block of memory cells contains four sub-blocks of memory cells. The example of Figure 7F differs from the structure of Figure 5A by depicting solid channel material structures 244, the further inclusion of doped sections 766, and the elimination of the GG gates 222 and their control line 226. The doped sections 766 might have a lower concentration of an impurity than the doped sections 452 and 454. The channel material structures 244 for each of the sub-blocks of memory cells 240 might contain a doped section 766 spanning across each of the select lines 330. In this manner, formation of the doped sections 766 could be formed without masking off any of the channel material structures 244. Following formation of the doped sections 452 and 454, the pre-configured select gates 328 could have threshold voltages similar to that described with reference to Figure 7E, along with the associated benefits. The doped sections 766 might have different, e.g., lower, impurity levels than the doped sections 452 and 454. For example, the doped sections 452 or 454 might have an impurity concentration of 2E19/cm ^A 3, while the doped sections 766 might have an impurity concentration of lE19/cm ^A 3.

[0124] Figure 8 depicts a use of varying select line thicknesses for use with embodiments. For embodiments utilizing more than two select lines 218 for each sub-block of memory cells 240, the inner select lines 218 might be thicker than outer select lines 218. Figure 8 depicts a grouping of three select lines 218, e.g., select lines 218xo, 218xi and 218x2. With reference to Figure 5A as an example, X might represent 0, 1, 2 and/or 3. As depicted, the inner select line 218xi might have a thickness thkl that is greater than a thickness thk2 of the outer select lines 218xo and 218x2. A thicker inner select line 218 might enhance carrier injection during programming and reduce short channel effects, and might produce a higher threshold voltage in the inner select lines 218 than in the edge select lines 218 during programming.

[0125] Figures 9A-9E depict conceptualized representations of cross-sectional views of portions of an array structure in accordance with alternate embodiments as could be used in a memory of the type described with reference to Figure 1. While prior embodiments utilized corresponding sets of select lines 218 for each sub-block of memory cells 240, this can lead to larger numbers of select lines 218 as the number of sub-blocks of memory cells 240 per block of memory cells 242 increases. Also, prior embodiments might not facilitate providing for threshold voltages of select gates 212 beyond a programmed state or an erased state, and there may be advantages to having two levels of programmed states, e.g., two different positive threshold voltages, during erase operations. To mitigate this increase in the number of select lines 218, and to facilitate programming of each select gate 212 to a desired threshold voltage, a coded binary approach might be used. Figures 9A-9E provide examples of such embodiments.

[0126] The array structure of Figure 9A includes select lines 33Oo and 330i, similar to the example of Figure 5 A. However, the array structure of Figure 9A further includes complementary select lines 93Oo and 930i. Complementary select gates 928 formed at intersections of the select lines 93Oo and 930i and the channel material structures 244 might have threshold voltages that are complementary to the threshold voltages of transistors (e.g., select gates 328) formed at intersections of the select lines 33Oo and 330i and the channel material structures 244. Dummy select line 464 could be used to optionally mitigate E-field and reduce program disturb between the transistors connected to select lines 218, and the transistors connected to adjacent select line 930. Complementary select gates (e.g., transistors) 928 formed at intersections of a channel material structure 244 and a complementary select line 930 might utilize a structure similar to (e.g., the same as) the memory cells 208 of Figure 3A. Transistors 408 formed at intersections of a channel material structure 244 and dummy select line 464 might utilize a structure similar to (e.g., the same as) the memory cells 208 of Figure 3 A.

[0127] A transistor (e.g., pre-configured select gate 328) formed at an intersection of a select line 330 and a channel material structure 244 might have either a threshold voltage lower than a first voltage level and higher than a second voltage level, e.g., having a doped section 452 or 454, or a threshold voltage lower than the second voltage level, e.g., not having a doped section 452 or 454, or having a doped section having a lower concentration of an impurity than a doped section 452 or 454. The first instance, e.g., the higher threshold voltage, might be deemed a logical 1 while the second instance, e.g., the lower threshold voltage, might be deemed a logical 0. Similarly, a transistor (e.g., complementary select gate 928) formed at an intersection of a select line 930 and a channel material structure 244 might have either a threshold voltage lower than a third voltage level and higher than a fourth voltage level, e.g., programmed, or a threshold voltage lower than the fourth voltage level, e.g., unprogrammed. Note that while the first voltage level and the third voltage level might be equal, and the second voltage level and the fourth voltage level might be equal, there is no need for either condition to be satisfied. Like the transistors formed at intersections of a select line 330 and a channel material structure 244, a transistor formed at an intersection of a select line 930 and a channel material structure 244 might be deemed a logical 1 if it has the higher threshold voltage, e.g., programmed, and might be deemed a logical 0 if the has the lower threshold voltage, e.g., unprogrammed.

[0128] Considering the example of Figure 9A, of the set of select lines 33Oo and 330i and the set of select lines 93Oo and 930i, the select line 33Oo might correspond to the select line 93Oo as its complement, and the select line 330i might correspond to the select line 930i as its complement. As such, transistors connected to the select line 93 Oo might have complementary threshold voltages to the threshold voltages of transistors connected to its corresponding select line 33Oo, and transistors connected to the select line 930i might have complementary threshold voltages to the threshold voltages of transistors connected to its corresponding select line 330i. As the logical states of the threshold voltages of the transistors at intersections of the select line 33Oo and channel material structures 244s. 2442, 244i and 244o are 1, 0, 1 and 0, respectively, the logical states of the threshold voltages of the transistors at intersections of its corresponding select line 93 Oo and channel material structures 244s, 2442, 244i and 244o might be 0, 1, 0 and 1, respectively. Similarly, as the logical states of the threshold voltages of the transistors at intersections of the select line 330i and channel material structures 244s, 2442, 244i and 244o are 1, 1, 0 and 0, respectively, the logical states of the threshold voltages of the transistors at intersections of its corresponding select line 930i and channel material structures 244s, 2442, 244i and 244o might be 0, 0, 1 and 1, respectively. Note that a select line 330 need not correspond to a select line 930 in the same relative positioning. For example, the select line 33Oo could instead correspond to the select line 930i and the select line 330i could instead correspond to the select line 93Oo provided that the complementary nature of the threshold voltages for the corresponding select line 930 is maintained, e.g., programming transistors 928 connected to select line 93Oo as depicted in Figure 9A for select line 930i, and programming transistors 928 connected to select line 930i as depicted in Figure 9A for select line 93Oo.

[0129] The array structure of Figure 9A might further include select lines 918, e.g., select lines 918o-9182, that might optionally be used in any embodiment to provide additional cutoff when no sub-block of memory cells 240 of a block of memory cells is selected for an access operation, and might further provide additional cut-off in unselected sub-blocks of memory cells 240 of the block of memory cells selected for the access operation. Select gates 912 formed at intersections of a channel material structure 244 and a select line 918 might utilize a structure similar to (e.g., the same as) the memory cells 208 of Figure 3 A.

[0130] After fabrication of the pre-configured select gates 328, the complementary select gates 928 might be programmed to have complementary threshold voltages. The complementary select gates 928 at intersections of the select line 93Oo with channel material structures 2441 and 244s might be programmed by concurrently enabling them for programming while inhibiting transistors of the channel material structures 244o and 2442 from programming. This might be accomplished by applying pass voltages to the control line 226, the select line 330i, the select line 450, and the select line 930i, and applying a voltage level to the select line 33Oo configured to activate pre-configured select gates 328 having the lower threshold voltage and to deactivate pre-configured select gates 328 having the higher threshold voltage. A programming voltage might then be applied to the select line 93 Oo to program the complementary select gates 928 at intersections with the channel material structures 2441 and 244s.

[0131] The complementary select gates 928 at intersections of the select line 930i with channel material structures 2442 and 244s might be programmed by concurrently enabling them for programming while inhibiting transistors of the channel material structures 244o and 244i from programming. This might be accomplished by applying pass voltages to the control line 226, the select line 33Oo, and the select line 450, and applying a voltage level to the select line 330i configured to activate pre-configured select gates 328 having the lower threshold voltage and to deactivate pre-configured select gates 328 having the higher threshold voltage. A programming voltage might then be applied to the select line 930i to program the complementary select gates 928 at intersections with the channel material structures 2442 and 244s.

[0132] Subsequent to programming the complementary select gates 928, the select gates 212, and any optional select gates 912, might be programmed. In particular, subsequent to programming the complementary select gates 928, each channel material structure 244 might be individually enabled for programming. For example, voltage levels corresponding to the logic levels low, low, high and high for the select lines 330i, 33Oo, 930i and 93Oo, respectively, could be used to connect select gates 212 formed at intersections of the channel material structure 244s to the data line 204 while isolating select gates 212 formed at intersections of the channel material structures 244o, 2441 and 2442 from the data line 204; voltage levels corresponding to the logic levels low, high, high and low for the select lines 330i, 33Oo, 930i and 93Oo, respectively, could be used to connect select gates 212 formed at intersections of the channel material structure 2442 to the data line 204 while isolating select gates 212 formed at intersections of the channel material structures 244o, 244i and 244s from the data line 204; voltage levels corresponding to the logic levels high, low, low and high for the select lines 330i, 33Oo, 930i and 93Oo, respectively, could be used to connect select gates 212 formed at intersections of the channel material structure 2441 to the data line 204 while isolating select gates 212 formed at intersections of the channel material structures 244o, 2442 and 244s from the data line 204; and voltage levels corresponding to the logic levels high, high, low and low for the select lines 330i, 33Oo, 930i and 93Oo, respectively, could be used to connect select gates 212 formed at intersections of the channel material structure 244o to the data line 204 while isolating select gates 212 formed at intersections of the channel material structures 244i, 2442 and 244s from the data line 204.

[0133] The select gates 212 connected to select lines 218o-2183 might be programmed to have threshold voltages having the same binary permutation of two threshold voltages as their corresponding pre-configured select gates 328 and complementary select gates 928 to which they are serially connected. For example, where the pre-configured select gates 328 connected to the select lines 330i and 33Oo, and the complementary select gates 928 connected to the select lines 930i and 93Oo, have threshold voltages corresponding to the logic levels low, low, high and high as depicted in Figure 9A, the select gates 212 connected to the select lines 218s, 2182, 2181 and 218o, might have the logic levels low, low, high and high, respectively. As such, the select gate 212 connected to the select line 2183 might be programmed to have a low threshold voltage, e.g., 2V; the select gate 212 connected to the select line 2182 might be programmed to have the low threshold voltage; the select gate 212 connected to the select line 2181 might be programmed to have a high threshold voltage, e.g., 4V; and the select gate 212 connected to the select line 218o might be programmed to have the high threshold voltage. Programming of select gates 212 might utilize an iterative process of applying a programming pulse to a programmable transistor and verifying if that transistor has reached a desired threshold voltage in response to that programming pulse, and repeating that iterative process until that transistor passes the verification. Note that for some embodiments, the low threshold voltage might be an initial threshold voltage, which might include remaining unprogrammed, e.g., remaining in an erased state.

[0134] Programming of threshold voltages of the select gates 212, and optional select gates 912, might proceed sequentially from a transistor closest to the common source 216, e.g., a select gate 912 connected to select line 918o, to a transistor closest to the data line 204, e.g., a select gate 212 connected to select line 2183, as is typical. Programming of threshold voltages of the select gates 212, and optional select gates 912, for one channel material structure 244 might be completed prior to the programming of threshold voltages of the select gates 212, and optional select gates 912, for a different channel material structure 244.

[0135] Following programming of the select gates 212, each sub-block of memory cells 240 can be individually selected, e.g., connected to the data line 204, by applying pass voltages to any line between the select lines 218 and the data line 204, and by applying voltage levels matching the logic levels of the programmed threshold voltages of the select gates 212 for the selected sub-block of memory cells 240. As such, programming of memory cells of a particular sub-block of memory cells 240 could proceed using an iterative process as previously described. For example, while a programming voltage is applied to the control gate of a selected memory cell of the particular sub-block of memory cells 240, pass voltages might be applied to any line between the select lines 218 and the data line 204 (e.g., control lines 226, select lines 330, dummy select lines 450 / 462 / 464, complementary select lines 930, etc.), voltage levels might be applied to the select lines 218 that correspond to the logic levels of the programmed threshold voltages of the select gates 212 to access the particular sub-block of memory cells 240 and isolate the remaining sub-blocks of memory cells 240 sharing the select lines 218, and pass voltages might be applied to any other lines (e.g., dummy select lines 460, select lines 918, access lines 202 to other memory cells, etc.) that are between the selected memory cell and the data line 204.

[0136] During a programming operation, if the data line 204 receives an inhibit voltage, e.g., a supply voltage Vcc, the select gates 912 formed at intersections of the channel material structures 244 and the select lines 918 might be deactivated as in a conventional NAND program inhibit scenario, resulting in channel boosting of the memory cells, and a resulting inhibit of programming of memory cells receiving the programming voltage. If the data line 204 receives an enable voltage, e.g., a reference potential Vss or ground, the select gates 912 formed at intersections of a channel material structure 244 of a selected sub-block of memory cells 240 and the select lines 918 might be activated to permit programming of its memory cell selected for the programming operation. However, the select gates 912 formed at intersections of the channel material structures 244 of the corresponding unselected subblocks of memory cells 240 and the select lines 918 might be deactivated. In particular, with a transistor (e.g., a select gate 212, or optionally a complementary select gate 328, and/or a complementary select gate 928) between the select gates 912 of an unselected sub-block of memory cells 240 and the data line 204 receiving a voltage level at its control gate below its threshold voltage, the potential of the channel region between the select gates 912 and the deactivated transistor might be expected to quickly rise, causing a back-bias effect to deactivate the select gates 912 of the unselected sub-blocks of memory cells 240 despite receiving a pass voltage, similar to a conventional NAND program inhibit scenario, along with the resulting channel boosting of the memory cells, and inhibiting of programming of the corresponding memory cells receiving the programming voltage. The additional cut-off afforded by the deactivated select gates 912 of the unselected sub-blocks of memory cells 240 might facilitate the use of a single transistor (e.g., a single select gate 212) being deactivated in each of the unselected sub-blocks of memory cells 240 during programming of a memory cell of a selected sub-block of memory cells 240 sharing a same data line 204.

[0137] Reading of memory cells of a particular sub-block of memory cells 240 could proceed by applying a read voltage to the access line 202 connected to a selected memory cell of the particular sub-block of memory cells 240, applying voltage levels to the select lines 218 that correspond to the logic levels of the programmed threshold voltages of the select gates 212 to access the particular sub-block of memory cells 240 and isolate the remaining sub-blocks of memory cells 240 sharing the select lines 218, and applying pass voltages to each remaining line (e.g., control lines 226, select lines 330, dummy select lines 450 / 460 / 462 / 464, select lines 918, complementary select lines 930, access lines 202 to other memory cells, select lines 214, control lines 224, etc.) that are between the data line 204 and the common source 216 for the particular sub-block of memory cells 240. In this manner, the existence or lack of current flow through the particular sub-block of memory cells 240, e.g., from the data line 204 to the common source 216, could indicate whether the selected memory cells is activated or deactivated, respectively, in response to the read voltage, thus providing information regarding its data state. Due to the lower potentials involved in a read operation versus a programming operation, no additional cut-off from select gates 912 would be necessary.

[0138] The array structure of Figure 9B is similar to the array structure of Figure 9A, but eliminates select gates 212 programmed to match the logic levels of the complementary select gates 328 connected to select line 930i and 93Oo. Programming of the complementary select gates 928, and the subsequent programming of the select gates 212, and any optional select gates 912, can proceed as described with reference to Figure 9A.

[0139] Following programming of the complementary select gates 928 and the select gates 212, each sub-block of memory cells 240 can be individually selected, e.g., connected to the data line 204, by applying pass voltages to any line between the select lines 930 and the data line 204, applying pass voltages to the dummy select lines 450 and 464, and by applying voltage levels matching the logic levels of the programmed threshold voltages of the complementary select gates 928 and select gates 212 for the selected sub-block of memory cells 240.

[0140] The array structure of Figure 9C is similar to the array structure of Figure 9A, but programs select gates 212 similar to the manner described with reference to Figure 5 A. However, instead of utilizing an initial, e.g., erased, threshold voltage as the low threshold voltage, those select gates 212 might be programmed to have a positive threshold voltage, e.g., 2V, while the select gates 212 having the high threshold voltage might be programed to have a higher positive threshold voltage, e.g., 4V. Programming of the complementary select gates 928, and the subsequent programming of the select gates 212, can proceed as described with reference to Figure 9A. Selection of sub-blocks of memory cells 240 might be performed as described with reference to Figure 5 A.

[0141] The array structure of Figure 9D is similar to the array structure of Figure 9A. The example of Figure 9D programs select gates 212 similar to the manner described with reference to Figure 5 A, but only utilizes one select gate 212 having the high threshold voltage for each channel material structure 244. To provide the added cut-off provided by the multiple select gates 212 having the high threshold voltage as depicted in Figure 5 A, the example of Figure 9D further incorporates select gates 912 connected to one or more select lines 918. Programming of the complementary select gates 928, and the subsequent programming of the select gates 212 and 912, can proceed as described with reference to Figure 9A. Selection of sub-blocks of memory cells 240 might be performed as described with reference to Figure 5 A.

[0142] The array structure of Figure 9E is similar to the array structure of Figure 9A, but modified to provide for selection of eight sub-blocks of memory cells 240. The preconfigured select gates 328 might be defined as described with reference to Figure 6A. Complementary select gates 928 connected to select line 93Oo might be enabled for programming by applying pass voltages to the lines between select line 93Oo and the data line 204 other than the select line 33Oo. The select line 33Oo might then receive a voltage level configured to activate pre-configured select gates 328 of channel material structures 2442, 244s, 2446 and 244?, and to deactivate pre-configured select gates 328 of channel material structures 244o, 244i, 2444 and 244s.

[0143] Complementary select gates 928 connected to select line 930i might be enabled for programming by applying pass voltages to the lines between select line 930i and the data line 204 other than the select line 330i. The select line 330i might then receive a voltage level configured to activate pre-configured select gates 328 of channel material structures 244i, 244s, 2445 and 244?, and to deactivate pre-configured select gates 328 of channel material structures 244o, 2442, 2444 and 244e.

[0144] Complementary select gates 928 connected to select line 9302 might be enabled for programming by applying pass voltages to the lines between select line 9302 and the data line 204 other than the select line 3302. The select line 3302 might then receive a voltage level configured to activate pre-configured select gates 328 of channel material structures 2444, 244s, 2446 and 244?, and to deactivate pre-configured select gates 328 of channel material structures 244o, 244i, 2442 and 244s.

[0145] Note that in the various foregoing embodiments, the channel material structures 244, and thus the strings of series-connected memory cells were depicted in specific orders laterally along their data line. However, while the depicted embodiments might minimize a number of masks utilized to fabricate the doped sections, any order of the desired binary permutations of two threshold voltages is acceptable. Thus, with reference to the embodiment of Figure 5 A as an example, if the channel material structures 244s, 2442, 244i and 244o are assigned numbers 4, 3, 2 and 1, respectively, they could be arranged laterally as 1234, 1324, 1423, 1432, 2134, 2314, 2413, 2431, 3124, 3214, 3412, 3421, 4123, 4213, 4312, and 4321.

[0146] Figures 10A-10K depict an integrated circuit structure, which might correspond to a portion of a channel material structure and associated structures of Figure 5 A, during various stages of fabrication in accordance with an embodiment. For example, Figures 10A- 10K might depict fabrication of an upper portion of the channel material structure 244o of Figure 5 A and the transistors formed at the intersection of the GG control line 226, SGPi select line 330i, SGPo select line 33Oo, dummy select line 450, and drain select line 21832. Figures 10A-10K might be used to depict fabrication of an array of memory cells in accordance with an embodiment, for example.

[0147] In Figure 10A, K+l instances of a dielectric 1002 (e.g., lOO2o to 1002K) and K instances of a sacrificial material 1004 (e.g., lOO4o to 1004K-I) might be formed in an alternating manner. Although instances of the dielectric 1 OO2O-1 OO2K-6, and instances of sacrificial material 1OO4O-1OO4K-6, are not explicitly depicted in the figures, it will be understood that an instance of the dielectric lOO2o could be formed overlying a common source 216 (e.g., formed on a contact to the common source 216), the instance of the sacrificial material lOO4o could be formed on the instance of the dielectric lOO2o, and subsequent instances of the dielectric 1002 and sacrificial material 1004 could be formed in an alternating manner as depicted in the figures.

[0148] The value K might represent the number of transistors to be formed around the channel material structure 244o of Figure 5 A between a connection to a common source 216 and a data line 204. The instances of the dielectric 1002 might each contain one or more dielectric materials. The instances of dielectric 1002 might comprise, consist of, or consist essentially of an oxide, e.g., silicon dioxide (SiCh), and/or might comprise, consist of, or consist essentially of a high-K dielectric material, such as aluminum oxides (AlOx), hafnium oxides (HfOx), hafnium aluminum oxides (HfAlOx), hafnium silicon oxides (HfSiOx), lanthanum oxides (LaOx), tantalum oxides (TaOx), zirconium oxides (ZrOx), zirconium aluminum oxides (ZrAlOx), or yttrium oxide (Y2O3), as well as any other dielectric material. High-K dielectrics as used herein means a material having a dielectric constant greater than that of silicon dioxide. The instances of dielectric 1002 might further comprise, consist of, or consist essentially of a spin-on dielectric material, e.g., hydrogen silsesquioxane (HSQ), hexamethyldisiloxane, octamethyltrisiloxane, etc., or a high-density -plasma (HDP) oxide. The instances of dielectric 1002 might further comprise, consist of, or consist essentially of any other dielectric material. As one example, the instances of the dielectric 1002 might contain silicon dioxide.

[0149] The instances of the sacrificial material 1004 might contain a material that can be subjected to removal without significantly affecting the material(s) of the dielectric 1002. As one example, the instances of the sacrificial material 1004 might contain silicon nitride for instances of the dielectric 1002 containing silicon dioxide. Additional instances of the dielectric 1002 and instances of the sacrificial material 1004 might be formed, depending upon the number of transistors intended to be formed, e.g., memory cells, dummy memory cells, GIDL generator gates, select gates and pre-configured select gates. While all intended instances of the dielectric 1002 and instances of the sacrificial material 1004 might be formed before proceeding to the processing of Figure 10B, typical processing of such stacked structures might be performed in stages as the aspect ratio of a via formed through the instances of the dielectric 1002 and the instances of the sacrificial material 1004 might become too large to form the entire structure reliably as a contiguous entity. [0150] In Figure 10B, a via 1006 might be formed through the instances of the dielectric 1002 and the instances of the sacrificial material 1004. For example, an anisotropic removal process, e.g., reactive ion etching (RIE), might be used with a contact to the common source 216 (not depicted in Figure 10B) acting as an etch stop. As such, the via 1006 might extend through all instances of the dielectric 1002 and through all instances of the sacrificial material 1004.

[0151] In Figure 10C, a channel material structure 244o might be formed to line the sidewalls of the via 1006, e.g., formed along the sidewalls of the instances of the dielectric 1002 and the instances of the sacrificial material 1004. The portion 1008 of the channel material structure 1010 is depicted in further detail in the expanded portion 1008'. As depicted, the channel material structure 244o might include a charge-blocking material 1012 formed to line the via 1006, a charge-storage material 1014 might be formed on the chargeblocking material 1012, a dielectric (e.g., gate dielectric) 1016 might be formed on the charge-storage material 1014, and a channel material (e.g., a semiconductor or conductively- doped semiconductor) 1018 might be formed on the dielectric 1016. The charge-storage material 1014 might contain a dielectric or conductive charge-storage material. The chargestorage material 1014 might further contain both dielectric and conductive materials, e.g., conductive nano-particles in a dielectric bulk material. For charge-storage material 1014 containing a conductive material as its bulk, or as a continuous structure, resulting memory cells might typically be referred to as floating-gate memory cells. For charge-storage material 1014 containing a dielectric material as its bulk, or as a continuous structure, resulting memory cells might typically be referred to as charge-trap memory cells. For one embodiment, the charge-blocking material 1012, charge-storage material 1014 and dielectric 1016 might form an ONO structure. The channel material 1018 might be a portion of a contiguous semiconductor structure for each transistor formed around the channel material structure 244o, or might otherwise be electrically connected, which might include selectively electrically connected, to channels of each such transistor. The channel material 1018 might have a conductivity type, e.g., a p-type conductivity or an n-type conductivity.

[0152] The charge-blocking material 1012 might function as a charge-blocking node for future memory cells and other transistors having a same structure, and might include one or more dielectric materials, such as described with reference to the dielectric 1002. For example, the charge-blocking material 1012 might include a high-K dielectric material. The charge-storage material 1014 might function as a charge-storage node for future memory cells and other transistors having a same structure, and might include one or more conductive or dielectric materials capable of storing a charge. For example, the charge-storage material 1014 might include silicon nitride, which has charge trapping levels inside the film. The dielectric 1016 might function as a gate dielectric for future memory cells and other transistors having a same structure, and might include one or more dielectric materials such as described with reference to the dielectric 1002. The channel material 1018 might function as a channel for future memory cells and other transistors having a same structure, and might include one or more semiconductor materials.

[0153] In Figure 10D, a dielectric 1040 might be formed in the void 1006. The dielectric 1040 might contain one or more dielectric materials. The dielectric 1040 might comprise, consist of, or consist essentially of an oxide, e.g., silicon dioxide (SiCh). The dielectric 1040 might further comprise, consist of, or consist essentially of a spin-on dielectric material, e.g., hydrogen silsesquioxane (HSQ), hexamethyldisiloxane, octamethyltrisiloxane, etc., or a high- density-plasma (HDP) oxide. The dielectric 1040 might further comprise, consist of, or consist essentially of any other dielectric material. The dielectric 1040 might contain one or more dielectric materials that can be selectively removed without adversely affecting the materials of the instances of dielectric 1002, the charge-blocking material 1012, the chargestorage material 1014, the dielectric 1016, and the channel material 1018. The dielectric 1040 might be deposited overlying the structure of Figure 10C, and then removed to the level of an upper surface of the upper instance of dielectric 1002, e.g., instance of dielectric 1002K, such as by chemical -mechanical planarization (CMP). A portion of the void 1006 might remain after forming the dielectric 1040. The dielectric 1040 might serve to mitigate contamination of portions of channel material 1018 corresponding to memory cells or other transistors that are not the target of future conductive doping as described infra with respect to Figures 10I-10J.

[0154] In Figure 10E, a portion of the dielectric 1040 might be removed to recess the upper surface of the dielectric 1040. For example, the dielectric 1040 might be recessed to expose portions of the channel material structure, and its channel material 1018, to a level of the upper instance of sacrificial material 1004, e.g., instance of sacrificial material 1004K-I. In Figure 10F, a conductive plug 1042 might be formed overlying the dielectric 1040 and in contact with the channel material 1018 of the channel material structure 244o. The conductive plug 1042 might contain one or more conductive materials, e.g., conductive materials such as described with reference to the conductor 1024. For some embodiments, the conductive plug 1042 might contain an n ⁺ -type conductively-doped polysilicon.

[0155] In Figure 10G, the instances of sacrificial material 1004 might be removed to define voids 1020, e.g., voids 1020K-I to 1020K-5. The removal might include an isotropic removal process, e.g., a plasma etching process. In Figure 10H, instances of an optional charge-blocking material 1022, e.g., instances of charge-blocking material 1022K-I to 1022K-5, might be formed to line the voids 1020, e.g., voids 1020K-I to 1020K-5, respectively. The instances of charge-blocking material 1022 might include one or more dielectric materials, such as described with reference to the dielectric 1002, and might include a high-K dielectric material. For embodiments with the charge-blocking material 1012, the instances of chargeblocking material 1022 might function as an additional charge-blocking material of a chargeblocking node for future memory cells and other transistors having a same structure. For embodiments without the charge-blocking material 1012, the instances of charge-blocking material 1022 might function individually as a charge-blocking node for future memory cells and other transistors having a same structure. For embodiments with the charge-blocking material 1012, and without the instances of charge-blocking material 1022, the chargeblocking material 1012 might function individually as a charge-blocking node for future memory cells and other transistors having a same structure. Instances of a conductor 1024, e.g., instances of a conductor 1024K-I to 1024K-5, might be formed to fill the voids 1020, e.g., voids 1020K-I to 1020K-5, respectively. The instances of the conductor 1024 might contain one or more conductive materials. The instances of the conductor 1024 might comprise, consist of, or consist essentially of conductively doped polysilicon and/or might comprise, consist of, or consist essentially of metal, such as a refractory metal, or a metal-containing material, such as a refractory metal silicide or a metal nitride, e.g., a refractory metal nitride, as well as any other conductive material.

[0156] A transistor might be formed at each intersection of an instance of the conductor 1024 and the channel material 1018, where an instance of the conductor 1024 might function as a control gate of the transistor, adjacent channel material 1018 might function as a channel of the transistor, and an instance of charge-blocking material 1022 and/or charge-blocking material 1012, charge-storage material 1014, and dielectric 1016 between the instance of the conductor 1024 and the adjacent channel material 1018 might function as a charge-blocking node, charge-storage node and gate dielectric, respectively, of that transistor. Such transistors could include memory cells 208, GIDL generator gates 220 and 222, select gates 210 and 212, and pre-configured select gates 328, for example.

[0157] In this example corresponding to the structure of Figure 5 A, the instance of the conductor 1024K-I might correspond to the control line 226, the instance of the conductor 1024K-2 might correspond to the select line 330i, the instance of the conductor 1024K-3 might correspond to the select line 33Oo, the instance of the conductor 1024K-4 might correspond to the dummy line 450, and the instance of the conductor 1024K-5 might correspond to the select line 21832. These correspondences are reflected beginning in Figure 101.

[0158] In Figure 101, portions of the channel material structure 244o, e.g., its channel material 1018, adjacent the select line 33Oo might be doped using a dopant impurity configured to increase a threshold voltage of the pre-configured select gate 328 to be formed at the intersection of the channel material structure 244o and the select line 33Oo. This might define a doped section 452. For purposes herein, a dopant impurity is an ion, element or molecule, or some combination of ions, elements and/or molecules, selectively added to the channel material 1018. Such doping might involve the acceleration of the dopant impurity, as depicted conceptually by arrows 1026. As one example, the dopant impurity might be a p- type impurity, such as ions of boron (B) or another p-type impurity. Alternatively, the dopant impurity might be an n-type impurity, such as ions of arsenic (As), antimony (Sb), phosphorus (P) or another n-type impurity. The dopant impurity might further be any other impurity that could be added to the channel material 1018 to facilitate an increase in threshold voltage. Examples of suitable doping processes might include plasma doping (PLAD) and/or beam-line implantation. Note that a counter implant of an opposite type might be used where lateral side scattering of the dopant impurity occurs during the definition of the doped section 452. For example, where a p-type dopant impurity, e.g., boron, is used to define the doped section 452, an n-type dopant impurity, e.g., phosphorous, might be used to compensate unwanted boron injection to the upper, e.g., shallower, portion of the channel.

[0159] A mask 1028, e.g., a photolithographic mask, might be used to cover channel material structures 244 (e.g., channel material structures 2442 and 2443) that are not to receive a doped section 452, and to expose channel material structures 244 (e.g., channel material structures 244o and 244i) that are to receive a doped section 452. Although depicted in Figure 101 to surround the channel material structure 244o, the mask 1028 might simply be a rectangular mask extending over all channel material structures 244 of a block of memory cells that are not to receive the doped section 452. For example, with reference to Figure 5B, the mask 1028 could be a rectangle that overlies the channel material structures 244 of the sub-blocks of memory cells 2402 and 240s, and has an edge extending along the dotted line between the sub-blocks of memory cells 240i and 2402. An anneal process might be used to diffuse the implanted dopant impurity within portions of the channel material 1018, thereby further defining the doped section 452.

[0160] In Figure 10J, portions of the channel material structure 244o adjacent the select line 330i might be doped using a dopant impurity configured to increase a threshold voltage of the pre-configured select gate 328 to be formed at the intersection of the channel material structure 244o and the select line 330i to define the doped section 454. Such doping might involve the acceleration of the dopant impurity, as depicted conceptually by arrows 1030. The doping depicted conceptually in Figure 10J by arrows 1030 might use a lower power than the doping depicted conceptually in Figure 101 by arrows 1026 to place the dopant impurity closer to the surface. Note that a counter implant of an opposite type might be used where lateral side scattering of the dopant impurity occurs during the definition of the doped section 454. For example, where a p-type dopant impurity, e.g., boron, is used to define the doped section 454, an n-type dopant impurity, e.g., phosphorous, might be used to compensate unwanted boron injection to the upper, e.g., shallower, portion of the channel.

[0161] A mask 1032, e.g., a photolithographic mask, might be used to cover channel material structures 244 (e.g., channel material structures 244i and 244s) that are not to receive a doped section 454, and to expose channel material structures 244 (e.g., channel material structures 244o and 2442) that are to receive a doped section 454. Although depicted in Figure 10J to surround the channel material structure 244o, the mask 1032 might simply be a rectangular mask extending over all channel material structures 244 of a block of memory cells that are not to receive the doped section 454. For example, with reference to Figure 5B, the mask 1032 could include a first rectangle that overlies the channel material structures 244 of the sub-block of memory cell 240i, and has edges extending along the dotted lines between the sub-blocks of memory cells 24Oo and 2401 and between the sub-blocks of memory cells 240i and 2402. The mask 1032 could further include a second rectangle that overlies the channel material structures 244 of the sub-block of memory cell 240s, and has an edge extending along the dotted line between the sub-blocks of memory cells 2402 and 240s and between the sub-blocks of memory cells 240i and 2402. An anneal process might be used to diffuse the implanted dopant impurity within portions of the channel material 1018, thereby further defining the doped section 454.

[0162] In Figure 10K, a data line contact 458 might be formed through a dielectric 1034 that might be formed overlying the structure of Figure 10J. The data line contact 458 might be formed to be in contact with the conductive plug 1042. A data line 204 might be formed overlying the data line contact 458. The data line 204 might be connected to the channel material 1018 of the channel material structure 244o through the contact 458 and conductive plug 1042. The contact 458 might contain one or more conductive materials, e.g., conductive materials such as described with reference to the conductor 1024. For some embodiments, the contact 458 might contain an n ⁺ -type conductively-doped polysilicon. For other embodiments, the contact 458 might include an n ⁺ -type conductively-doped polysilicon formed overlying the channel material structure 244o, titanium nitride (TiN) formed overlying the n ⁺ -type conductively-doped polysilicon, and tungsten (W) formed overlying the titanium nitride. For further embodiments, the upper portion of the channel material 1018 of the channel material structure 244o might be doped to an n ⁺ -type conductivity, and the contact 458 might include titanium nitride (TiN) formed overlying the channel material structure 244o, and tungsten (W) formed overlying the titanium nitride. While Figures 10A-10K depicted an example method of fabricating a portion of the array structure of Figure 5 A, other methods of fabrication could be used with various embodiments.

[0163] Figure 11 is a flowchart of a method of operating an apparatus, e.g., a memory, in accordance with an embodiment. The method might be in the form of computer-readable instructions, e.g., stored to the instruction registers 128. Such computer-readable instructions might be executed by a controller, e.g., the control logic 116, to cause the relevant components of the apparatus to perform the method.

[0164] At 1101, a first field-effect transistor between a first string of series-connected memory cells and a data line might be activated concurrently with deactivating a second field-effect transistor between a second string of series-connected memory cells and the data line. The first field-effect transistor and the second field-effect transistor might have their control gates connected to a same select line. For example, the first field-effect transistor and the second field-effect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 330 and the channel material structures 244i and 244o, respectively, of Figure 4A. Alternatively, the first field-effect transistor and the second fieldeffect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 330i and the channel material structures 244s and 2442, respectively, of Figure 5 A. Alternatively, the first field-effect transistor and the second fieldeffect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 330i and the channel material structures 244? and 244e, respectively, of Figure 6A.

[0165] At 1103, a third field-effect transistor between the first string of series-connected memory cells and the first field-effect transistor might be programmed concurrently with inhibiting programming of a fourth field-effect transistor between the second string of series- connected memory cells and the second field-effect transistor. The third field-effect transistor and the fourth field-effect transistor might have their control gates connected to a same select line. For example, the third field-effect transistor and the fourth field-effect transistor might correspond to the select gates formed at the intersections of the select line 218io and the channel material structures 244i and 244o, respectively, of Figure 4A. Alternatively, the third field-effect transistor and the fourth field-effect transistor might correspond to the select gates formed at the intersections of the select line 21830 and the channel material structures 244s and 2442, respectively, of Figure 5 A. Alternatively, the third field-effect transistor and the fourth field-effect transistor might correspond to the select gates formed at the intersections of the select line 21870 and the channel material structures 244? and 2446, respectively, of Figure 6A.

[0166] At 1105, the first field-effect transistor might be activated concurrently with activating the second field-effect transistor, deactivating the third field-effect transistor, and activating the fourth field-effect transistor. At 1107, a fifth field-effect transistor between the first string of series-connected memory cells and the third field-effect transistor might be inhibited from programming concurrently with programming a sixth field-effect transistor between the second string of series-connected memory cells and the fourth field-effect transistor. The fifth field-effect transistor and the sixth field-effect transistor might have their control gates connected to a same select line. For example, the fifth field-effect transistor and the sixth field-effect transistor might correspond to the select gates formed at the intersections of the select line 21800 and the channel material structures 244i and 244o, respectively, of Figure 4A. Alternatively, the fifth field-effect transistor and the sixth field-effect transistor might correspond to the select gates formed at the intersections of the select line 21820 and the channel material structures 244s and 2442, respectively, of Figure 5 A. Alternatively, the fifth field-effect transistor and the sixth field-effect transistor might correspond to the select gates formed at the intersections of the select line 218eo and the channel material structures 244? and 244e, respectively, of Figure 6A.

[0167] Figure 12 is a flowchart of a method of operating an apparatus, e.g., a memory, in accordance with an embodiment. The method might be in the form of computer-readable instructions, e.g., stored to the instruction registers 128. Such computer-readable instructions might be executed by a controller, e.g., the control logic 116, to cause the relevant components of the apparatus to perform the method.

[0168] At 1211, a first field-effect transistor and a second field-effect transistor between a first string of series-connected memory cells and a data line might be activated concurrently with activating a third field-effect transistor and a fourth field-effect transistor between a second string of series-connected memory cells and the data line, deactivating a fifth fieldeffect transistor and activating a sixth field-effect transistor between a third string of series- connected memory cells and the data line, and deactivating a seventh field-effect transistor and activating an eighth field-effect transistor between a fourth string of series-connected memory cells and the data line.

[0169] The first field-effect transistor, the third field-effect transistor, the fifth field-effect transistor, and the seventh field-effect transistor might have their control gates connected to a same select line. For example, the first field-effect transistor, the third field-effect transistor, the fifth field-effect transistor, and the seventh field-effect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 33Oo and the channel material structures 244s. 244i, 2442, and 244o, respectively, of Figure 9A. Alternatively, the first field-effect transistor, the third field-effect transistor, the fifth field-effect transistor, and the seventh field-effect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 330i and the channel material structures 244?, 244s, 2446, and 2444, respectively, of Figure 9E.

[0170] The second field-effect transistor, the fourth field-effect transistor, the sixth fieldeffect transistor, and the eighth field-effect transistor might have their control gates connected to a same select line. For example, the second field-effect transistor, the fourth field-effect transistor, the sixth field-effect transistor, and the eighth field-effect transistor might correspond to the pre-configured select gates formed at the intersections of the select line 330i and the channel material structures 244s, 244i, 2442, and 244o, respectively, of Figure 9 A. Alternatively, the second field-effect transistor, the fourth field-effect transistor, the sixth field-effect transistor, and the eighth field-effect transistor might correspond to the preconfigured select gates formed at the intersections of the select line 33Oo and the channel material structures 244?, 244s, 244e, and 2444, respectively, of Figure 9E.

[0171] At 1213, a ninth field-effect transistor between the first string of series-connected memory cells and the first field-effect transistor might be programmed concurrently with programming a tenth field-effect transistor between the second string of series-connected memory cells and the third field-effect transistor, inhibiting programming of an eleventh field-effect transistor between the third string of series-connected memory cells and the fifth field-effect transistor, and inhibiting programming of a twelfth field-effect transistor between the fourth string of series-connected memory cells and the seventh field-effect transistor. The ninth field-effect transistor, the tenth field-effect transistor, the eleventh field-effect transistor, and the twelfth field-effect transistor might have their control gates connected to a same select line. For example, the ninth field-effect transistor, tenth field-effect transistor, eleventh field-effect transistor, and twelfth field-effect transistor might correspond to the complementary select gates formed at the intersections of the select line 93Oo and the channel material structures 244s. 244i, 2442, and 244o, respectively, of Figure 9A. Alternatively, the ninth field-effect transistor, tenth field-effect transistor, eleventh field-effect transistor, and twelfth field-effect transistor might correspond to the complementary select gates formed at the intersections of the select line 930i and the channel material structures 244?, 244s, 244e, and 2444, respectively, of Figure 9E.

[0172] The ninth field-effect transistor might further be between the first string of series- connected memory cells and the second field-effect transistor, the tenth field-effect transistor might further be between the second string of series-connected memory cells and the fourth field-effect transistor, the eleventh field-effect transistor might further be between the third string of series-connected memory cells and the sixth field-effect transistor, and the twelfth field-effect transistor might further be between the fourth string of series-connected memory cells and the eighth field-effect transistor.

[0173] At 1215, the first field-effect transistor and the second field-effect transistor might be activated concurrently with activating the third field-effect transistor and deactivating the fourth field-effect transistor, activating the fifth field-effect transistor and the sixth fieldeffect transistor, and activating the seventh field-effect transistor and deactivating the eighth field-effect transistor.

[0174] At 1217, a thirteenth field-effect transistor between the first string of series- connected memory cells and the first field-effect transistor might be programmed concurrently with inhibiting programming of a fourteenth field-effect transistor between the second string of series-connected memory cells and the third field-effect transistor, programming a fifteenth field-effect transistor between the third string of series-connected memory cells and the fifth field-effect transistor, and inhibiting programming of a sixteenth field-effect transistor between the fourth string of series-connected memory cells and the seventh field-effect transistor. The thirteenth field-effect transistor, the fourteenth field-effect transistor, the fifteenth field-effect transistor, and the sixteenth field-effect transistor might have their control gates connected to a same select line. For example, the thirteenth fieldeffect transistor, fourteenth field-effect transistor, fifteenth field-effect transistor, and sixteenth field-effect transistor might correspond to the complementary select gates formed at the intersections of the select line 930i and the channel material structures 244s. 244i, 2442, and 244o, respectively, of Figure 9A. Alternatively, the thirteenth field-effect transistor, fourteenth field-effect transistor, fifteenth field-effect transistor, and sixteenth field-effect transistor might correspond to the complementary select gates formed at the intersections of the select line 93Oo and the channel material structures 244?, 244s, 244e, and 2444, respectively, of Figure 9E.

[0175] The thirteenth field-effect transistor might further be between the first string of series-connected memory cells and the second field-effect transistor, the fourteenth fieldeffect transistor might further be between the second string of series-connected memory cells and the fourth field-effect transistor, the fifteenth field-effect transistor might further be between the third string of series-connected memory cells and the sixth field-effect transistor, and the sixteenth field-effect transistor might further be between the fourth string of series- connected memory cells and the eighth field-effect transistor. In addition, the ninth fieldeffect transistor might further be between the first string of series-connected memory cells and the thirteenth field-effect transistor, the tenth field-effect transistor might further be between the second string of series-connected memory cells and the fourteenth field-effect transistor, the eleventh field-effect transistor might further be between the third string of series-connected memory cells and the fifteenth field-effect transistor, and the twelfth fieldeffect transistor might further be between the fourth string of series-connected memory cells and the sixteenth field-effect transistor.

[0176] Figure 13 is a flowchart of a method of operating an apparatus, e.g., a memory, in accordance with an embodiment. The method might be in the form of computer-readable instructions, e.g., stored to the instruction registers 128. Such computer-readable instructions might be executed by a controller, e.g., the control logic 116, to cause the relevant components of the apparatus to perform the method.

[0177] At 1321, a first set of field-effect transistors between a first string of series- connected memory cells and a data line might be programmed to have a complementary binary permutation of two threshold voltages to a binary permutation of two threshold voltages of a second set of field-effect transistors between the first set of field-effect transistors and the data line. The first set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 244s and the select lines 93Oo and 930i of Figure 9A or 9B, while the second set of field-effect transistors might be the pre-configured select gates formed at intersections of the channel material structure 244s and the select lines 33Oo and 330i of Figure 9A or 9B, respectively. Alternatively, the first set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 244? and the select lines 93Oo, 930i, and 9302 of Figure 9E, while the second set of field-effect transistors might be the preconfigured select gates formed at intersections of the channel material structure 244? and the select lines 33Oo, 330i, and 3302 of Figure 9E.

[0178] At 1323, a third set of field-effect transistors between a second string of series- connected memory cells and the data line might be programmed to have a complementary binary permutation of two threshold voltages to a binary permutation of two threshold voltages of a fourth set of field-effect transistors between the third set of field-effect transistors and the data line. The third set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 2442 and the select lines 93Oo and 930i of Figure 9A or 9B, while the fourth set of field-effect transistors might be the pre-configured select gates formed at intersections of the channel material structure 2442 and the select lines 33Oo and 330i of Figure 9A or 9B, respectively. Alternatively, the third set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 244e and the select lines 93Oo, 930i, and 9302 of Figure 9E, while the fourth set of field-effect transistors might be the preconfigured select gates formed at intersections of the channel material structure 244e and the select lines 33Oo, 330i, and 3302 of Figure 9E.

[0179] For each position of the binary permutation of two threshold voltages of the first set of field-effect transistors, a field-effect transistor of the first set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the first set of field-effect transistors, and a field-effect transistor of the third set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the third set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line.

[0180] For each position of the binary permutation of two threshold voltages of the second set of field-effect transistors, a field-effect transistor of the second set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the second set of field-effect transistors, and a field-effect transistor of the fourth set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the fourth set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line.

[0181] Programming of the first set of field-effect transistors might be performed sequentially, and programming of the third set of field-effect transistors might be performed sequentially. For example, if the first set of field-effect transistors includes the complementary select gates formed at intersections of the channel material structure 244s and the select lines 93Oo and 930i of Figure 9A, the complementary select gate formed at the intersection of the channel material structure 244s and the select line 93 Oo might be subjected to a first programming operation (e.g., either programmed or inhibited from programming), and the complementary select gate formed at the intersection of the channel material structure 244s and the select line 930i might then be subjected to a second programming operation (e.g., either programmed or inhibited from programming). In addition, programming of the first and third sets of field-effect transistors might occur concurrently. To continue with the example, the complementary select gates formed at intersections of the select line 93Oo and the channel material structures 2442 and 244s might be subjected (e.g., concurrently) to the first programming operation (e.g., either programmed or inhibited from programming), and the complementary select gates formed at intersections of the select line 930i and the channel material structures 2442 and 244s might be subjected (e.g., concurrently) to the second programming operation (e.g., either programmed or inhibited from programming). As used herein, a set of field-effect transistors will be deemed to be programmed to have its binary permutation of two threshold voltages even if each field-effect transistor of that set of fieldeffect transistors is to remain at an initial, e.g., erased, threshold voltage during the one or more programming operations.

[0182] At 1325, a fifth set of field-effect transistors between the first string of series- connected memory cells and the first set of field-effect transistors might be programmed to have a same binary permutation of two threshold voltages as the binary permutation of two threshold voltages of the second set of field-effect transistors. The fifth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244s and the select lines 2182 and 2183 of Figure 9A. Alternatively, the fifth set of fieldeffect transistors might be the select gates formed at intersections of the channel material structure 244s and the select lines 2180 and 2181 of Figure 9B. Alternatively, the fifth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244? and the select lines 218s, 2184, and 218s of Figure 9E.

[0183] At 1327, a sixth set of field-effect transistors between the second string of series- connected memory cells and the third set of field-effect transistors might be programmed to have a same binary permutation of two threshold voltages as the binary permutation of two threshold voltages of the fourth set of field-effect transistors. The sixth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 2182 and 2183 of Figure 9A. Alternatively, the sixth set of fieldeffect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 2180 and 2181 of Figure 9B. Alternatively, the sixth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244e and the select lines 218s, 2184, and 218s of Figure 9E.

[0184] For each position of the binary permutation of two threshold voltages of the fifth set of field-effect transistors, a field-effect transistor of the fifth set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the fifth set of field-effect transistors, and a field-effect transistor of the sixth set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the sixth set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line.

[0185] Similar to that discussed with reference to the first set of field-effect transistors and the third set of field-effect transistors, programming of the fifth set of field-effect transistors and programming of the sixth set of field-effect transistors might be performed sequentially through the individual field-effect transistors of those sets of field-effect transistors, and concurrently among those sets of field-effect transistors.

[0186] Optionally, at 1329, a seventh set of field-effect transistors between the first string of series-connected memory cells and the first set of field-effect transistors might be programmed to have a same binary permutation of two threshold voltages as the binary permutation of two threshold voltages of the first set of field-effect transistors. The seventh set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244s and the select lines 218o and 218i of Figure 9 A. Alternatively, the seventh set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244? and the select lines 218o, 218i, and 2182 of Figure 9E.

[0187] Optionally, at 1331, an eighth set of field-effect transistors between the second string of series-connected memory cells and the third set of field-effect transistors might be programmed to have a same binary permutation of two threshold voltages as the binary permutation of two threshold voltages of the third set of field-effect transistors. The eighth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 2180 and 2181 of Figure 9 A. Alternatively, the eighth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244e and the select lines 218o, 2181, and 2182 of Figure 9E.

[0188] For each position of the binary permutation of two threshold voltages of the seventh set of field-effect transistors, a field-effect transistor of the seventh set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the seventh set of field-effect transistors, and a field-effect transistor of the eighth set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the eighth set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line. [0189] Similar to that discussed with reference to the first set of field-effect transistors and the third set of field-effect transistors, programming of the seventh set of field-effect transistors and programming of the eighth set of field-effect transistors might be performed sequentially through the individual field-effect transistors of those sets of field-effect transistors, and concurrently among those sets of field-effect transistors.

[0190] Figure 14 is a flowchart of a method of operating an apparatus, e.g., a memory, in accordance with an embodiment. The method might be in the form of computer-readable instructions, e.g., stored to the instruction registers 128. Such computer-readable instructions might be executed by a controller, e.g., the control logic 116, to cause the relevant components of the apparatus to perform the method.

[0191] At 1431, a first set of field-effect transistors between a first string of series- connected memory cells and a data line might be programmed to have a complementary binary permutation of two threshold voltages to a binary permutation of two threshold voltages of a second set of field-effect transistors between the first set of field-effect transistors and the data line. The first set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 244s and the select lines 93Oo and 930i of Figure 9C or 9D, while the second set of field-effect transistors might be the pre-configured select gates formed at intersections of the channel material structure 244s and the select lines 33Oo and 330i of Figure 9C or 9D, respectively.

[0192] At 1433 a third set of field-effect transistors between a second string of series- connected memory cells and the data line might be programmed to have a complementary binary permutation of two threshold voltages to a binary permutation of two threshold voltages of a fourth set of field-effect transistors between the third set of field-effect transistors and the data line. The third set of field-effect transistors might be the complementary select gates formed at intersections of the channel material structure 2442 and the select lines 93Oo and 930i of Figure 9C or 9D, while the fourth set of field-effect transistors might be the pre-configured select gates formed at intersections of the channel material structure 2442 and the select lines 33Oo and 330i of Figure 9C or 9D, respectively.

[0193] For each position of the binary permutation of two threshold voltages of the first set of field-effect transistors, a field-effect transistor of the first set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the first set of field-effect transistors, and a field-effect transistor of the third set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the third set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line.

[0194] For each position of the binary permutation of two threshold voltages of the second set of field-effect transistors, a field-effect transistor of the second set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the second set of field-effect transistors, and a field-effect transistor of the fourth set of field-effect transistors corresponding to that position of the binary permutation of two threshold voltages of the fourth set of field-effect transistors, might be connected (e.g., have their respective control gates connected) to a same select line.

[0195] Programming of the first set of field-effect transistors might be performed sequentially, and programming of the third set of field-effect transistors might be performed sequentially. For example, if the first set of field-effect transistors includes the complementary select gates formed at intersections of the channel material structure 244s and the select lines 93Oo and 930i of Figure 9C, the complementary select gate formed at the intersection of the channel material structure 244s and the select line 93 Oo might be subjected to a first programming operation (e.g., either programmed or inhibited from programming), and the complementary select gate formed at the intersection of the channel material structure 244s and the select line 930i might then be subjected to a second programming operation (e.g., either programmed or inhibited from programming). In addition, programming of the first and third sets of field-effect transistors might occur concurrently. To continue with the example, the complementary select gates formed at intersections of the select line 93Oo and the channel material structures 2442 and 244s might be subjected (e.g., concurrently) to the first programming operation (e.g., either programmed or inhibited from programming), and the complementary select gates formed at intersections of the select line 930i and the channel material structures 2442 and 244s might be subjected (e.g., concurrently) to the second programming operation (e.g., either programmed or inhibited from programming). As used herein, a set of field-effect transistors will be deemed to be programmed to have its binary permutation of two threshold voltages even if each field-effect transistor of that set of fieldeffect transistors is to remain at an initial, e.g., erased, threshold voltage during the one or more programming operations. [0196] At 1435, a fifth set of field-effect transistors between the first string of series- connected memory cells and the first set of field-effect transistors might be programmed to each have a first threshold voltage, and a sixth set of field-effect transistors between the first string of series-connected memory cells and the fifth set of field-effect transistors might be programmed to each have a second threshold voltage lower than the first threshold voltage. The fifth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 244s and the select lines 21830, 21831 and 2I832 of Figure 9C, and the sixth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2443 and the select lines 2I820, 21821 and 2I822 of Figure 9C. Alternatively, the fifth set of field-effect transistors might be the select gate formed at the intersection of the channel material structure 2443 and the select line 2183 of Figure 9D, and the sixth set of field-effect transistors might be the select gate formed at the intersection of the channel material structure 2443 and the select line 2182 of Figure 9D.

[0197] Similar to that discussed with reference to the first set of field-effect transistors and the third set of field-effect transistors, programming of the fifth set of field-effect transistors and programming of the sixth set of field-effect transistors might be performed sequentially through the individual field-effect transistors of those sets of field-effect transistors. For example, the field-effect transistors of the sixth set of field-effect transistors might be programmed from bottom to top, then the field-effect transistors of the fifth set of field-effect transistors might be programmed from bottom to top. For embodiments having more than two sub-blocks of memory cells, additional sets of field-effect transistors, e.g., the select gates formed at intersections of the channel material structure 2443 and the select lines 218oo, 218oi, 2I802, 218io, 218ii, and 21812 of Figure 9C, might be programmed, e.g., sequentially programmed, to have the second threshold voltage prior to programming the sixth set of field-effect transistors.

[0198] At 1437, a seventh set of field-effect transistors between the second string of series-connected memory cells and the third set of field-effect transistors might be programmed to each have the second threshold voltage, and an eighth set of field-effect transistors between the second string of series-connected memory cells and the seventh set of field-effect transistors might be programmed to each have the first threshold voltage. The seventh set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 2I830, 21831 and 2I832 of Figure 9C, and the eighth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 2I820, 21821 and 2I822 of Figure 9C. Alternatively, the seventh set of field-effect transistors might be the select gate formed at the intersection of the channel material structure 2442 and the select line 2183 of Figure 9D, and the eighth set of field-effect transistors might be the select gate formed at the intersection of the channel material structure 2442 and the select line 2182 of Figure 9D.

[0199] Similar to that discussed with reference to the first set of field-effect transistors and the third set of field-effect transistors, programming of the seventh set of field-effect transistors and programming of the eighth set of field-effect transistors might be performed sequentially through the individual field-effect transistors of those sets of field-effect transistors. For example, the field-effect transistors of the eighth set of field-effect transistors might be programmed from bottom to top, then the field-effect transistors of the seventh set of field-effect transistors might be programmed from bottom to top. For embodiments having more than two sub-blocks of memory cells, additional sets of field-effect transistors, e.g., the select gates formed at intersections of the channel material structure 2442 and the select lines 218oo, 218oi, 2I802, 218io, 218ii, and 21812 of Figure 9C, might be programmed, e.g., sequentially programmed, to have the second threshold voltage prior to programming the eighth set of field-effect transistors.

[0200] Optionally, at 1439, a ninth set of field-effect transistors between the first string of series-connected memory cells and the sixth set of field-effect transistors might be programmed to have the first threshold voltage and a tenth set of field-effect transistors between the second string of series-connected memory cells and the eighth set of field-effect transistors might be programmed to have the first threshold voltage. The ninth set of fieldeffect transistors might be the select gates formed at intersections of the channel material structure 244s and the select lines 9180, 9181, and 9182 of Figure 9D, and the tenth set of field-effect transistors might be the select gates formed at intersections of the channel material structure 2442 and the select lines 918o, 9181, and 9182 of Figure 9D

CONCLUSION

[0201] Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement that is calculated to achieve the same purpose might be substituted for the specific embodiments shown. Many adaptations of the embodiments will be apparent to those of ordinary skill in the art. Accordingly, this application is intended to cover any adaptations or variations of the embodiments.