Abstract: A microelectronic device comprises a stack structure comprising blocks each including a vertically alternating sequence of conductive material and insulative material arranged in tiers, at least one of the blocks comprising: a memory array region having vertically extending strings of memory cells within a horizontal area thereof; and a staircase region horizontally neighboring the memory array region. The staircase structure has steps comprising horizontal ends of the tiers; and a crest sub-region horizontally interposed between the staircase structure and the memory array region. A masking structure overlies the stack structure and has a different material composition than each of the conductive material and the insulative material. Filled slot structures are interposed between the blocks of the stack structure, at least one of the filled slot structures comprises at least one fill material that has an uppermost boundary vertically underlying an uppermost boundary of the masking structure.

Abstract: Some embodiments include an integrated assembly having a first memory region, a second memory region, and an intermediate region between the memory regions. A stack extends across the memory regions and the intermediate region. The stack includes alternating conductive levels and insulative levels. Channel-material-pillars are arranged within the memory regions. Memory-block-regions extend longitudinally across the memory regions and the intermediate region. Staircase regions are within the intermediate region. Each of the staircase regions laterally overlaps two of the memory-block-regions. First panel regions extend longitudinally across at least portions of the staircase regions. Second panel regions extend longitudinally and provide lateral separation between adjacent memory-block-regions. The second panel regions are of laterally different dimensions than the first panel regions and/or are compositionally different than the first panel regions.

Abstract: Microelectronic devices include a stack structure having a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. A series of stadiums, within the stack structure, includes stadiums of differing numbers of staircase sets, such as a stadium having multiple parallel sets of staircases and an additional stadium having a single set of staircases. Each of the staircases comprises steps, at ends of the conductive structures, with a same multi-tier riser height. In methods of fabrication, a same initial stadium opening may be concurrently formed for each of the stadiums—regardless of whether the stadium is to include the single set or the multiple parallel sets of staircases—with the steps of the same multi-tier riser height. Electronic systems are also disclosed.

Abstract: A microelectronic device includes a stack structure having blocks separated by dielectric slot structures and each including a vertically alternating sequence of conductive structures and insulative structures arranged in tiers. At least one of the blocks includes an upper stadium structure, two crest regions, a lower stadium structure, and two bridge regions. The upper stadium structure extends from and between two of the dielectric slot structures, and includes staircase structures having steps including edges of some of the tiers. The two crest regions are horizontally offset from the upper stadium structure. The lower stadium structure is below the upper stadium structure, is interposed between the two crest regions, and includes additional staircase structures. The two bridge regions are interposed between the lower stadium structure and the two of the dielectric slot structures, and extend between the two crest regions. Related memory devices, electronic systems, and methods are also described.

Abstract: A termination opening can be formed through the stack alternating dielectrics concurrently with forming contact openings through the stack. A termination structure can be formed in the termination opening. An additional opening can be formed through the termination structure and through the stack between groups of semiconductor structures that pass through the stack. In another example, an opening can be formed through the stack so that a first segment of the opening is between groups of semiconductor structures in a first region of the stack and a second segment of the opening is in a second region of the stack that does not include the groups of semiconductor structures. A material can be formed in the second segment so that the first segment terminates at the material. In some instances, the material can be implanted in the dielectrics in the second region through the second segment.

Abstract: Methods, systems, and devices for transition structures for three-dimensional memory arrays are described. A memory device may include a staircase region which includes a set of vias. The set of vias may include a first subset of vias which couple respective word line plates of the memory region with associated word line decoders, and a second subset of vias which are electrically isolated from the word line plates. The second subset of vias may be arranged in one or more rows positioned between the first subset of vias and the memory region. In some cases, the second subset of vias may be positioned above respective conductive contacts. Additionally or alternatively, the second subset of vias may be positioned above a common conductor shared with pillars of the memory region.

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 slit region divides the stack structure into blocks. Each block comprises an array of active pillars. Along the at least one slit region is a horizontally alternating sequence of slit structure segments and support pillar structures. The slit structure segments and the support pillar structures each extend vertically through the stack structure. Additional microelectronic devices are also disclosed as are related methods and electronic systems.

Abstract: Some embodiments include an integrated assembly having a first memory region, a second memory region, and an intermediate region between the memory regions. A stack extends across the memory regions and the intermediate region. The stack includes alternating conductive levels and insulative levels. Channel-material-pillars are arranged within the memory regions. Memory-block-regions extend longitudinally across the memory regions and the intermediate region. Staircase regions are within the intermediate region. Each of the staircase regions laterally overlaps two of the memory-block-regions. First panel regions extend longitudinally across at least portions of the staircase regions. Second panel regions extend longitudinally and provide lateral separation between adjacent memory-block-regions. The second panel regions are of laterally different dimensions than the first panel regions and/or are compositionally different than the first panel regions.

Abstract: A method of forming a microelectronic device includes forming a microelectronic device structure. The microelectronic device structure includes a stack structure comprising insulative structures and electrically conductive structures vertically alternating with the insulative structures, pillar structures extending vertically through the stack structure, an etch stop material vertically overlaying the stack structure, and a first dielectric material vertically overlying the etch stop material. The method further includes removing portions of the first dielectric material, the etch stop material, and an upper region of the stack structure to form a trench interposed between horizontally neighboring groups of the pillar structures, forming a liner material within the trench, and substantially filling a remaining portion of the trench with a second dielectric material to form a dielectric barrier structure.

Abstract: A method used in forming a memory array and conductive through-array-vias (TAVs) comprises forming a stack comprising vertically-alternating insulative tiers and wordline tiers. A mask is formed comprising horizontally-elongated trench openings and operative TAV openings above the stack. Etching is conducted of unmasked portions of the stack through the trench and operative TAV openings in the mask to form horizontally-elongated trench openings in the stack and to form operative TAV openings in the stack. Conductive material is formed in the operative TAV openings in the stack to form individual operative TAVs in individual of the operative TAV openings in the stack. A wordline-intervening structure is formed in individual of the trench openings in the stack.

Abstract: A method of forming a microelectronic device comprises forming a microelectronic device structure. The microelectronic device structure comprises a stack structure comprising insulative structures and additional insulative structures vertically alternating with the insulative structures, a dielectric structure vertically extending partially through the stack structure, and a dielectric material vertically overlying and horizontally extending across the stack structure and the dielectric structure. Portions of at least the dielectric material and the dielectric structure are removed to form a trench vertically overlying and at least partially horizontally overlapping a remaining portion of the dielectric structure. The trench is substantially filled with additional dielectric material. Microelectronic devices, memory devices, and electronic systems are also described.

Abstract: A memory array comprising strings of memory cells comprise laterally-spaced memory blocks individually comprising a vertical stack comprising alternating insulative tiers and conductive tiers directly above a conductor tier. Strings of memory cells comprise channel-material strings that extend through the insulative tiers and the conductive tiers. The channel-material strings directly electrically couple with conductor material of the conductor tier. A through-array-via (TAV) region comprises TAV constructions that individually extend through the insulative tiers and the conductive tiers into the conductor tier. Individual of the TAV constructions comprise an upper portion directly above and joined with a lower portion. The individual TAV constructions comprise at least one external jog surface in a vertical cross-section where the upper and lower portions join. Other embodiments, including method, are disclosed.

Abstract: A memory array comprising strings of memory cells comprises laterally-spaced memory blocks individually comprising a vertical stack comprising alternating insulative tiers and conductive tiers. Operative channel-material strings of memory cells extend through the insulative tiers and the conductive tiers. The operative channel-material strings in the laterally-spaced memory blocks comprise part of a memory plane. An elevationally-extending wall is in the memory plane laterally-between immediately-laterally-adjacent of the memory blocks and that completely encircles an island that is laterally-between immediately-laterally-adjacent of the memory blocks in the memory plane. Other embodiments, including method are disclosed.

Abstract: Microelectronic devices include a stack structure with a vertically alternating sequence of insulative structures and conductive structures arranged in tiers. A series of slit structures extends through the stack structure and divides the stack structure into a series of blocks. In a progressed portion of the series of blocks, each block comprises an array of pillars extending through the stack structure of the block. Also, each block—in the progressed portion—has a different block width than a block width of a neighboring block of the progressed portion of the series of blocks. At least one pillar, of the pillars of the array of pillars in the progressed portion, exhibits bending. Related methods and electronic systems are also disclosed.

Abstract: A microelectronic device comprises a stack structure comprising a vertically alternating sequence of conductive structures and insulative structures arranged in tiers, a staircase structure within the stack structure having steps comprising horizontal edges of the tiers, a first insulative material vertically overlying the staircase structure, conductive contact structures comprising a conductive material extending through the first insulative material and in contact with the steps of the staircase structure, and a second insulative material extending in a first horizontal direction between horizontally neighboring conductive contact structures and exhibiting one or more different properties than the first insulative material. Related microelectronic devices, electronic systems, and methods are also described.

Abstract: Some embodiments include apparatuses and methods of forming the apparatuses. One of the apparatuses includes a first deck located over a substrate, and a second deck located over the first deck, and pillars extending through the first and second decks. The first deck includes first memory cells, first control gates associated with the first memory cells, and first conductive paths coupled to the first control gates. The second conductive paths include second conductive pads located on a first level of the apparatus over the substrate. The second deck includes second memory cells, second control gates associated with the second memory cells, and second conductive paths coupled to the second control gates. The second conductive paths include second conductive pads located on a second level of the apparatus. The first and second conductive pads having lengths in a direction perpendicular to a direction from the first deck to the second deck.

Abstract: Some embodiments include an integrated assembly having a source structure, and having a stack of alternating conductive levels and insulative levels over the source structure. Cell-material-pillars pass through the stack. The cell-material-pillars are arranged within a configuration which includes a first memory-block-region and a second memory-block-region. The cell-material-pillars include channel material which is electrically coupled with the source structure. Memory cells are along the conductive levels and include regions of the cell-material-pillars. A panel is between the first and second memory-block-regions. The panel has a first material configured as a container shape. The container shape defines opposing sides and a bottom of a cavity. The panel has a second material within the cavity. The second material is compositionally different from the first material. Some embodiments include methods of forming integrated assemblies.

Abstract: Some embodiments include an integrated assembly having a pair of adjacent memory-block-regions, and having a separator structure between the adjacent memory-block-regions. The memory-block-regions include a first stack of alternating conductive levels and first insulative levels. The separator structure includes a second stack of alternating second and third insulative levels. The second insulative levels are substantially horizontally aligned with the conductive levels, and the third insulative levels are substantially horizontally aligned with the first insulative levels. Some embodiments include methods of forming integrated assemblies.

Abstract: A memory array comprising strings of memory cells comprises laterally-spaced memory blocks individually comprising a vertical stack comprising alternating insulative tiers and conductive tiers above a conductor tier. Strings of memory cells comprise channel-material strings that extend through the insulative tiers and the conductive tiers. The channel-material strings directly electrically couple with conductor material of the conductor tier by conducting material that is in a lowest of the conductive tiers and that is directly against multiple of the channel-material strings. The channel-material strings in the laterally-spaced memory blocks comprise part of a memory plane. A wall in the lowest conductive tier is aside the conducting material. The wall is in a region that is edge-of-plane relative to the memory plane. The edge-of-plane region comprises a TAV region. The wall is horizontally-elongated relative to an edge of the TAV region that is in the edge-of-plane region.

Abstract: A microelectronic device, including a stack structure including alternating conductive structures and dielectric structures is disclosed. Memory pillars extend through the stack structure. Contacts are laterally adjacent to the memory pillars and extending through the stack structure. The contacts including active contacts and support contacts. The active contacts including a liner and a conductive material. The support contacts including the liner and a dielectric material. The conductive material of the active contacts is in electrical communication with the memory pillars. Methods and electronic systems are also disclosed.