Abstract: A microelectronic device includes a stack structure comprising a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. At least one pillar, comprising a channel material, extends through the stack structure. A source region, below the stack structure, comprises a doped material. A vertical extension of the doped material protrudes upward to an interface with the channel material at elevation within the stack structure (e.g., an elevation proximate or laterally overlapping in elevation at least one source-side GIDL region). The microelectronic device structure may be formed by a method that includes forming a lateral opening through cell materials of the pillar, recessing the channel material to form a vertical recess, and forming the doped material in the vertical recess. Additional microelectronic devices are also disclosed, as are related methods and electronic systems.

Abstract: An electronic device comprises a stack of alternating dielectric materials and conductive materials, a pillar region extending vertically through the stack, an oxide material within the pillar region and laterally adjacent to the dielectric materials and the conductive materials of the stack, and a storage node laterally adjacent to the oxide material and within the pillar region. A charge confinement region of the storage node is in horizontal alignment with the conductive materials of the stack. A height of the charge confinement region in a vertical direction is less than a height of a respective, laterally adjacent conductive material of the stack in the vertical direction. Related methods and systems are also disclosed.

Abstract: A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of select gate transistors to strings of memory cells. The channel structures can be implemented as a segmented portion for drains and a portion opposite a gate. The segmented portion includes one or more fins and one or more non-conductive regions with both fins and non-conductive regions extending vertically from the portion opposite the gate. Variations of a border region for the portion opposite the gate with the segmented portion can include fanged regions extending from the fins into the portion opposite the gate or rounded border regions below the non-conductive regions. Such select gate transistors can be formed using a single photo mask process. Additional devices, systems, and methods are discussed.

Abstract: Memory array structures, and methods of their formation, might include a first memory cell having a first control gate and an adjacent first portion of a charge-blocking structure, a second memory cell having a second control gate and an adjacent second portion of the charge-blocking structure, and a first dielectric material between the first control gate and the second control gate, and adjacent to a third portion of the charge-blocking structure that is between the first and second portions of the charge-blocking structure. The third portion of the charge-blocking structure might include a second dielectric material and a third dielectric material different than the second dielectric material, and the first portion of the charge-blocking structure and the second portion of the charge-blocking structure might each include the third dielectric material and a fourth dielectric material different than the second dielectric material. Apparatus might include such memory array structures.

Abstract: A method used in forming a memory array comprising strings of memory cells comprises forming a stack comprising vertically-alternating different-composition first tiers and second tiers. The stack comprises lower channel-material strings extending through the first tiers and the second tiers. Conductive masses are formed that comprise at least one of conductively-doped semiconductive material or conductive metal material. Individual of the conductive masses are atop and directly electrically coupled to individual of the lower channel-material strings. Upper channel-material strings of select-gate transistors are formed directly above the stack. Individual of the upper channel-material strings are directly above and directly electrically coupled to individual of the conductive masses. Other embodiments, including structure, are disclosed.

Abstract: Microelectronic devices include a stack structure comprising a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. A series of pillars extends through the stack structure. At least one isolation structure extends through an upper stack portion of the stack structure. The at least one isolation structure protrudes into pillars of neighboring columns of pillars of the series of pillars. Conductive contacts are in electrical communication with the pillars into which the at least one isolation structure protrudes. Related methods and electronic systems are also disclosed.

Abstract: A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of select gate transistors to strings of memory cells. The channel structures can be implemented as a segmented portion for drains and a portion opposite a gate. The segmented portion includes one or more fins and one or more non-conductive regions with both fins and non-conductive regions extending vertically from the portion opposite the gate. Variations of a border region for the portion opposite the gate with the segmented portion can include fanged regions extending from the fins into the portion opposite the gate or rounded border regions below the non-conductive regions. Such select gate transistors can be formed using a single photo mask process. Additional devices, systems, and methods are discussed.

Abstract: A semiconductor device comprises a stack comprising an alternating sequence of dielectric structures and conductive structures, and a channel structure within an opening vertically extending through the stack and comprising a first semiconductor material having a first band gap. The semiconductor device also comprises a conductive plug structure within the opening and in direct contact with the channel region, and a band offset structure within the opening and in direct physical contact with the channel structure and the conductive plug structure. The band offset structure comprises a second semiconductor material having a second band gap different than the first band gap. The semiconductor device further comprises a conductive line structure electrically coupled to the conductive plug structure. A method of forming a semiconductor device and an electronic system are also described.

Abstract: Methods, systems, and devices for NAND structures with polarized materials are described. A memory device may include a polarized dielectric material located relatively near to a channel, which may reduce interference between cells. The polarized dielectric material may include a dielectric material with a fixed polarity and having a first surface with a negative polarity oriented towards the channel. The negative polarity of the polarized dielectric material may affect an electron distribution of the channel by shifting the electron distribution closer to an associated charge trapping material. The shifted electron distribution may reduce an effect of an electric field of any aggressor cells of the memory device on one or more victim cells, by creating a more uniform channel electron distribution and increasing gate control relative to a channel without the effects of the polarized dielectric material.

Abstract: Microelectronic devices include a stack structure comprising a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. A series of pillars extends through the stack structure. At least one isolation structure extends through an upper stack portion of the stack structure. The at least one isolation structure protrudes into pillars of neighboring columns of pillars of the series of pillars. Conductive contacts are in electrical communication with the pillars into which the at least one isolation structure protrudes. Related methods and electronic systems are also disclosed.

Abstract: Some embodiments include apparatuses and methods of operating the apparatuses. One of the apparatuses includes a memory cell string having first, second, third, fourth, and fifth memory cells; access lines including first, second, third, fourth, and fifth access lines coupled to the first, second, third, fourth, and fifth memory cells, respectively, and a module. The first memory cell is between the second and third memory cells. The second memory cell is between the first and fourth memory cells. The third memory cell is between the first and fifth memory cells. The module is to couple the first access line to a ground node at a first time of a memory operation, couple the second and third access lines to the ground node at a second time of the operation after the first time, and couple the fourth and fifth access lines to the ground node at a third time of the operation after the second time.

Abstract: A semiconductor device comprises a stack comprising an alternating sequence of dielectric structures and conductive structures, and a channel structure within an opening vertically extending through the stack and comprising a first semiconductor material having a first band gap. The semiconductor device also comprises a conductive plug structure within the opening and in direct contact with the channel region, and a band offset structure within the opening and in direct physical contact with the channel structure and the conductive plug structure. The band offset structure comprises a second semiconductor material having a second band gap different than the first band gap. The semiconductor device further comprises a conductive line structure electrically coupled to the conductive plug structure. A method of forming a semiconductor device and an electronic system are also described.

Abstract: A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of the topmost select gate transistors to strings of memory cells upon application of a voltage to the gates of the topmost select gate transistors. This electric field can be provided by using a dissected plug as a contact to the channel structure of the topmost select gate transistor, where the dissected plug has one or more conductive regions contacting the channel structure and one or more non-conductive regions contacting the channel structure. The dissected plug can be part of a contact between the data line and the channel structure. Additional devices, systems, and methods are discussed.

Abstract: Some embodiments include a pillar which contains semiconductor material, and which extends primarily along a first direction. A cross-section through the pillar along a second direction orthogonal to the first direction is through the semiconductor material and includes a lateral periphery of the pillar configured as three-sided shape. Some embodiments include an integrated assembly having a vertical stack of alternating first and second levels. The first levels include conductive structures and the second levels are insulative. Channel-material-pillars extend through the vertical stack. Each of the channel-material-pillars has a top-down cross-section which includes a lateral periphery configured as three-sided shape of an equilateral triangle with rounded vertices.

Abstract: A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of select gate transistors to strings of memory cells. The channel structures can be implemented as a segmented portion for drains and a portion opposite a gate. The segmented portion includes one or more fins and one or more non-conductive regions with both fins and non-conductive regions extending vertically from the portion opposite the gate. Variations of a border region for the portion opposite the gate with the segmented portion can include fanged regions extending from the fins into the portion opposite the gate or rounded border regions below the non-conductive regions. Such select gate transistors can be formed using a single photo mask process. Additional devices, systems, and methods are discussed.

Abstract: Some embodiments include apparatuses and methods of forming the apparatuses. One of the apparatuses includes a memory cell included in a memory cell string; the memory cell including charge storage structure and channel structure separated from the charge storage structure by a dielectric structure; a first control gate associated with the memory cell and located on a first side of the charge storage structure and a first side of the channel structure; and a second control gate associated with the memory cell and electrically separated from the first control gate, the second control gate located on a second side of the charge storage structure and a second side of the channel structure.

Abstract: Some embodiments include apparatuses and methods of operating the apparatuses. One of the apparatuses includes a memory cell string having first, second, third, fourth, and fifth memory cells; access lines including first, second, third, fourth, and fifth access lines coupled to the first, second, third, fourth, and fifth memory cells, respectively, and a module. The first memory cell is between the second and third memory cells. The second memory cell is between the first and fourth memory cells. The third memory cell is between the first and fifth memory cells. The module is to couple the first access line to a ground node at a first time of a memory operation, couple the second and third access lines to the ground node at a second time of the operation after the first time, and couple the fourth and fifth access lines to the ground node at a third time of the operation after the second time.

Abstract: Some embodiments include an integrated assembly having a first deck. The first deck has first memory cell levels alternating with first insulative levels. A second deck is over the first deck. The second deck has second memory cell levels alternating with second insulative levels. A cell-material-pillar passes through the first and second decks. Memory cells are along the first and second memory cell levels and include regions of the cell-material-pillar. An intermediate level is between the first and second decks. The intermediate level includes a buffer region adjacent the cell-material-pillar. The buffer region includes a composition different from the first and second insulative materials, and different from the first and second conductive regions. Some embodiments include methods of forming integrated assemblies.

Abstract: A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of the topmost select gate transistors to strings of memory cells upon application of a voltage to the gates of the topmost select gate transistors. This electric field can be provided by using a dissected plug as a contact to the channel structure of the topmost select gate transistor, where the dissected plug has one or more conductive regions contacting the channel structure and one or more non-conductive regions contacting the channel structure. The dissected plug can be part of a contact between the data line and the channel structure. Additional devices, systems, and methods are discussed.

Abstract: Some embodiments include an integrated assembly having a first deck. The first deck has first memory cell levels alternating with first insulative levels. A second deck is over the first deck. The second deck has second memory cell levels alternating with second insulative levels. A cell-material-pillar passes through the first and second decks. Memory cells are along the first and second memory cell levels and include regions of the cell-material-pillar. An intermediate level is between the first and second decks. The intermediate level includes a buffer region adjacent the cell-material-pillar. The buffer region includes a composition different from the first and second insulative materials, and different from the first and second conductive regions. Some embodiments include methods of forming integrated assemblies.