Abstract: Embodiments of semiconductor devices and fabrication methods thereof are disclosed. In an example, a method for forming a semiconductor device is provided. The method includes the following operations. In a first semiconductor structure, a first bonding layer is formed having a first dielectric layer and a plurality of protruding contact structures. In a second semiconductor structure, a second bonding layer is formed having a second dielectric layer and a plurality of recess contact structures. The plurality of protruding contact structures are bonded with the plurality of recess contact structures such that each of the plurality of protruding contacts is in contact with a respective recess contact structure.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a P-type doped region of a substrate, an N-type doped semiconductor layer on the P-type doped region, a memory stack including interleaved conductive layers and dielectric layers on the N-type doped semiconductor layer, a channel structure extending vertically through the memory stack and the N-type doped semiconductor layer into the P-type doped region, an N-type doped semiconductor plug extending vertically into the P-type doped region, and a source contact structure extending vertically through the memory stack to be in contact with the N-type doped semiconductor plug.

Abstract: In a method for fabricating a semiconductor device, an initial stack of sacrificial word line layers and insulating layers is formed over a substrate of the semiconductor device. The sacrificial word line layers and the insulating layers are disposed over the substrate alternately. A first staircase is formed in a first staircase region of a connection region of the initial stack. A second staircase is formed in a second staircase region of the connection region of the initial stack. The connection region of the initial stack includes a separation region between the first and second staircases, and the connection region is positioned between array regions of the initial stack at opposing sides of the initial stack.

Abstract: Staircase structures for a three-dimensional (3D) memory device are disclosed. In some embodiments, the method includes disposing an alternating dielectric stack on a substrate with first and second dielectric layers alternatingly stacked on top of each other. Next, multiple division blocks can be formed in a staircase region. Each division block includes a first plurality of staircase steps in the first direction. Each staircase step in the first direction has two or more dielectric layer pairs. Then, a second plurality of staircase steps along a second direction, perpendicular to the first direction, can be formed. Each staircase step in the second direction includes the first plurality of staircase steps along the first direction. The method further includes forming an offset number of dielectric layer pairs between the multiple division blocks such that each dielectric layer pair is accessible from a top surface of a staircase step.

Abstract: Methods and structures of a three-dimensional memory device are disclosed. In an example, the method comprises: providing a substrate; forming an alternating stack over the substrate, the alternating stack comprising a plurality of tiers of sacrificial layer/insulating layer pairs extending along a first direction substantially parallel to a top surface of the substrate; forming a plurality of tiers of word lines extending along the first direction based on the alternating stack; forming at least one connection portion conductively connecting two or more of the word lines of the plurality of tiers of word lines; and forming at least one metal contact via conductively shared by connected word lines, the at least one metal contact via being connected to at least one metal interconnect.

Abstract: The present disclosure describes method and structure of a three-dimensional memory device. The memory device includes a substrate and a plurality of wordlines extending along a first direction over the substrate. The first direction is along the x direction. The plurality of wordlines form a staircase structure in a first region. A plurality of channels are formed in a second region and through the plurality of wordlines. The second region abuts the first region at a region boundary. The memory device also includes an insulating slit formed in the first and second regions and along the first direction. A first width of the insulating slit in the first region measured in a second direction is greater than a second width of the insulating slit in the second region measured in the second direction.

Abstract: Embodiments of 3D memory devices with a dielectric etch stop layer and methods for forming the same are disclosed. In an example, a method for forming a 3D memory device is disclosed. The method includes forming a dielectric etch stop layer. The dielectric etch stop is disposed on a substrate. The method also includes forming a dielectric stack on the dielectric etch stop layer. The dielectric stack includes a plurality of interleaved dielectric layers and sacrificial layers. The method further includes forming an opening extending vertically through the dielectric stack and extending the opening through the dielectric etch stop layer. In addition, the method includes forming a selective epitaxial growth (SEG) plug at a lower portion of the opening. The SEG plug is disposed on the substrate. Moreover, the method includes forming a channel structure above and in contact with the SEG plug in the opening.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a memory stack and a plurality of memory strings. The memory stack includes interleaved conductive layers and dielectric layers. Each memory string extends vertically through the memory stack. The plurality of memory strings are divided into a plurality of regions of the memory stack in a plan view. The conductive layers include one or more drain select gate (DSG) lines configured to control drains of the plurality of memory strings. The numbers of the DSG lines are different among the plurality of regions. Each of the plurality of memory strings has a nominally same height.

Abstract: Aspects of the disclosure provide a semiconductor device and a method for fabricating the same. The method for fabricating the semiconductor device can include forming a stack of alternating first insulating layers and first sacrificial layers over a semiconductor substrate, and forming a staircase in the stack having a plurality of steps, with at least a first step of the staircase including a first sacrificial layer of the first sacrificial layers over a first insulating layer of the first insulating layers. Further, the method can include forming a recess in the first sacrificial layer, forming a second sacrificial layer in the recess, and replacing a portion of the first sacrificial layer and the second sacrificial layer with a conductive material that forms a contact pad.

Abstract: 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.

Abstract: Embodiments of 3D memory devices having staircase structures and methods for forming the same are disclosed. In an example, the 3D memory device includes a memory array structure and a staircase structure. The staircase structure is located in an intermediate of the memory array structure and divides the memory array structure into a first memory array structure and a second memory array structure along a lateral direction. The staircase structure includes a plurality of stairs extending along the lateral direction, and a bridge structure in contact with the memory array structure. The stairs include a stair above one or more dielectric pairs. The stair includes a conductor portion electrically connected to the bridge structure and is electrically connected to the memory array structure through the bridge structure. Along a second lateral direction perpendicular to the lateral direction and away from the bridge structure, a width of the conductor portion decreases.

Abstract: Embodiments of 3D memory devices having staircase structures and methods for forming the same are disclosed. In an example, a 3D memory device includes a memory array structure and a staircase structure in an intermediate of the memory array structure. The staircase structure includes a plurality of stairs extending along the lateral direction, and a bridge structure in contact with the first memory array structure and the second memory array structure. The plurality of stairs includes a stair above one or more dielectric pairs The stair includes a conductor portion on a top surface of the stair and in contact with and electrically connected to the bridge structure, and is electrically connected to at least one of a first memory array structure and a second memory array structure of the memory array structure through the bridge structure. Along a second lateral direction, a width of the conductor portion is unchanged.

Abstract: Aspects of the disclosure provide a method for data erase in a memory device. The method includes providing first erase carriers from a body portion for the memory cell string, during an erase operation in a memory cell string. The first erase carriers flow in a first direction from a source side of the memory cell string to a drain side of the memory cell string. Further, the method includes providing second erase carriers from a junction at the drain side of the memory cell string. The second erase carriers flow in a second direction from the drain side of the memory cell string to the source side of the memory cell string. Then, the method includes injecting the first erase carriers and the second erase carriers to charge storage portions of the memory cells in the memory cell string.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a peripheral circuit on the substrate, a memory stack including interleaved conductive layers and dielectric layers above the peripheral circuit, an N-type doped semiconductor layer above the memory stack, a plurality of channel structures each extending vertically through the memory stack into the N-type doped semiconductor layer, and a source contact above the memory stack and in contact with the N-type doped semiconductor layer. An upper end of each of the plurality of channel structures is flush with or below a top surface of the N-type doped semiconductor layer.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a 3D memory device includes a substrate, a peripheral circuit on the substrate, a memory stack including interleaved conductive layers and dielectric layers above the peripheral circuit, an N-type doped semiconductor layer above the memory stack, a plurality of channel structures each extending vertically through the memory stack into the N-type doped semiconductor layer, a conductive layer in contact with upper ends of the plurality of channel structures, at least part of which is on the N-type doped semiconductor layer, and a source contact above the memory stack and in contact with the N-type doped semiconductor layer.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a method for forming a 3D memory device is disclosed. A sacrificial layer on a substrate, a first stop layer on the sacrificial layer, an N-type doped semiconductor layer on the first stop layer, and a dielectric stack on the N-type doped semiconductor layer are sequentially formed. A plurality of channel structures each extending vertically through the dielectric stack and the N-type doped semiconductor layer are formed, stopping at the first stop layer. The dielectric stack is replaced with a memory stack, such that each of the plurality of channel structures extends vertically through the memory stack and the N-type doped semiconductor layer. The substrate, the sacrificial layer, and the first stop layer are sequentially removed to expose an end of each of the plurality of channel structures. A conductive layer is formed in contact with the ends of the plurality of channel structures.

Abstract: Embodiments of 3D memory devices and methods for forming the same are disclosed. In an example, a method for forming a 3D memory device is disclosed. A sacrificial layer on a substrate, an N-type doped semiconductor layer on the sacrificial layer, and a dielectric stack on the N-type doped semiconductor layer are subsequently formed. A channel structure extending vertically through the dielectric stack and the N-type doped semiconductor layer is formed. The dielectric stack is replaced with a memory stack, such that the channel structure extends vertically through the memory stack and the N-type doped semiconductor layer. The substrate and the sacrificial layer are removed to expose an end of the channel structure. Part of the channel structure abutting the N-type doped semiconductor layer is replaced with a semiconductor plug.

Abstract: Memory device includes a bottom-select-gate (BSG) structure including cut slits vertically through the BSG structure, on a substrate. 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. A first gate-line slit is between first and second finger regions and includes gate-line sub-slits. The first finger region is divided into a first string region and a second string region by a first cut-slit, formed in the first finger region along a second lateral direction and further extended into at least the second finger region along the first lateral direction. At least one BSG defined by the first cut-slit is located in at least the second finger region to connect to cell strings in the first string region through an inter-portion between adjacent gate-line sub-slits.

Abstract: Memory device includes a bottom-select-gate (BSG) structure. Cut slits are formed vertically through the BSG structure, on a substrate. 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.

Abstract: Memory device includes a bottom-select-gate (BSG) structure. Cut slits are formed vertically through the BSG structure, on a substrate. 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.