Embodiments of source structure of a three-dimensional (3D) memory device and method for forming the source structure of the 3D memory device are disclosed. In an example, a NAND memory device includes a substrate, an alternating conductor/dielectric stack, a NAND string, a source conductor layer, and a source contact. The alternating conductor/dielectric stack includes a plurality of conductor/dielectric pairs above the substrate. The NAND string extends vertically through the alternating conductor/dielectric stack. The source conductor layer is above the alternating conductor/dielectric stack and is in contact with an end of the NAND string. The source contact includes an end in contact with the source conductor layer. The NAND string is electrically connected to the source contact by the source conductor layer. In some embodiments, the source conductor layer includes one or more conduction regions each including one or more of a metal, a metal alloy, and a metal silicide.

Memory device includes a bottom-select-gate (BSG) structure formed on a substrate. Cut slits are formed vertically through the BSG structure. A cell-layers structure is formed on the BSG structure. Gate-line slits are formed vertically through the cell-layers structure and the BSG structure, into the substrate and arranged along a first lateral direction to distinguish finger regions. The gate-line slits include a first gate-line slit between first and second finger regions, the first gate-line slit including gate-line sub-slits. The cut slits include a first cut-slit, formed in the second finger region and connecting to a gate-line sub-slit to define a BSG in a first portion of the second finger region. The BSG in the first portion of the second finger region is electrically connected to cell strings in the first finger region through an inter portion between the one gate-line sub-slit and an adjacent gate-line sub-slit.

Memory device includes a bottom-select-gate (BSG) structure formed on a substrate. Cut slits are formed vertically through the BSG structure. A cell-layers structure is formed on the BSG structure. Gate-line slits are formed vertically through the cell-layers structure and the BSG structure, into the substrate and arranged along a first lateral direction to distinguish finger regions. The gate-line slits include a first gate-line slit between first and second finger regions, the first gate-line slit including gate-line sub-slits. The cut slits include a first cut-slit, formed in the second finger region and connecting to a gate-line sub-slit to define a BSG in a first portion of the second finger region. The BSG in the first portion of the second finger region is electrically connected to cell strings in the first finger region through an inter portion between the one gate-line sub-slit and an adjacent gate-line sub-slit.

A non-volatile memory device and a non-volatile memory system comprising the same are provided. The non-volatile memory device includes a first stack in which a first conductive pattern and a first dielectric layer are alternately stacked in a first direction on a substrate, a second stack in which a second conductive pattern and a second dielectric layer are alternately stacked in the first direction on the first stack opposite the substrate, a first monitoring channel structure that penetrates the first stack in the first direction, and a second monitoring channel structure that penetrates the second stack in the first direction and is =on the first monitoring channel structure. A width of a top of the first monitoring channel structure opposite the substrate is smaller than a width of a bottom of the second monitoring channel structure adjacent the top of the first monitoring channel structure.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

Integrated circuitry comprises two three-dimensional (3D) array regions individually comprising tiers of electronic components. A stair-step region is between the two 3D-array regions. First stair-step structures alternate with second stair-step structures along a first direction within the stair-step region. The first stair-step structures individually comprise two opposing first flights of stairs in a first vertical cross-section along the first direction. The stairs in the first flights each have multiple different-depth treads in a second vertical cross-section that is along a second direction that is orthogonal to the first direction. The second stair-step structures individually comprise two opposing second flights of stairs in the first vertical cross-section. The stairs in the second flights each have only a single one tread along the second direction. Other embodiments, including method, are disclosed.

A three-dimensional semiconductor devices including a substrate, a stack structure including gate electrodes on the substrate and string selection electrodes spaced apart from each other on the gate electrodes, a first separation structure running in a first direction across the stack structure and being between the string selection electrodes, vertical channel structures penetrating the stack structure, and bit lines connected to the vertical channel structures and extending in a second direction may be provided. A first subset of the vertical channel structures is connected in common to one of the bit lines. The vertical channel structures of the first subset may be adjacent to each other in the second direction across the first separation structure. Each of the string selection electrodes may surround each of the vertical channel structures of the first subset.

A semiconductor device including a substrate including first, second, and third regions; a peripheral circuit structure on the substrate and including a peripheral circuit and wiring layers connected to the peripheral circuit; a common source plate on the peripheral circuit structure and extending in a horizontal direction; gate electrodes on the common source plate on the first and second regions, spaced apart from each other in a first direction perpendicular to an upper surface of the substrate, the gate electrodes having a stair shape on the second region; a channel structure extending in the first direction through the gate electrodes on the first region; a first conductive through-via penetrating the common source plate on the third region and electrically connected to the wiring layers; and a dummy insulating pillar adjacent to the first conductive through-via on the third region and connected to an upper surface of the common source plate.

Embodiments of contact structures of a three-dimensional memory device and fabrication method thereof are disclosed. The three-dimensional memory structure includes a film stack disposed on a substrate, wherein the film stack includes a plurality of conductive and dielectric layer pairs, each conductive and dielectric layer pair having a conductive layer and a first dielectric layer. The three-dimensional memory structure also includes a staircase structure formed in the film stack, wherein the staircase structure includes a plurality of steps, each staircase step having two or more conductive and dielectric layer pairs. The three-dimensional memory structure further includes a plurality of coaxial contact structures formed in a first insulating layer over the staircase structure, wherein each coaxial contact structure includes one or more conductive and insulating ring pairs and a conductive core, each conductive and insulating ring pair having a conductive ring and an insulating ring.

A semiconductor device includes a lower structure, stack structure including gate electrodes stacked and spaced apart from each other on a first region of the lower structure and extending in a staircase shape on a second region of the lower structure, and interlayer insulating layers alternately stacked with the gate electrodes, channel structures penetrating through the gate electrodes on the first region, and isolation structures penetrating through the gate electrodes spaced apart from each other. Each channel structure a channel bent portion between first and second channel structures. Each isolation structure includes a first isolation bent portion between first and second isolation structures and a second isolation bent portion between second and third isolation structures. A width of an upper surface of the second isolation structure is narrower than a width of a lower surface of the third isolation structure.