A memory die includes an alternating stack of insulating layers and electrically conductive layers through which memory opening fill structures vertically extend. The memory die includes at least three memory array regions interlaced with at least two contact regions, or at least three contact regions interlaced with at least two memory array regions in the same memory plane. A logic die including at least two word line driver regions can be bonded to the memory die. The interlacing of the contact regions and the memory array regions can reduce lateral offset of boundaries of the word line driver regions from boundaries of the contact regions.

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.

Described is a semiconductor memory device and methods of manufacture. The semiconductor memory device comprises a memory array comprising at least one select-gate-for-drain (SGD) transistor and at least one memory transistor, the memory array having at least one strapping region and at least one strapping contact, the strapping contact connecting a select-gate-for-drain (SGD) transistor to a strapping line.

A vertical-type nonvolatile memory device is provided in which differences between the sizes of channel holes in which channel structures are formed are reduced. The vertical-type nonvolatile memory device includes a substrate having channel hole recess regions in a surface thereof. Channel structures vertically protrude from the surface of the substrate on ones of the channel hole recess regions, and memory cell stacks including insulating and conductive layers are alternately stacked along sidewalls of the channel structures. A common source line extends along the surface of the substrate on other ones of the channel hole recess regions in a word line recess region, which separates adjacent memory cell stacks. Related fabrication methods are also discussed.

A vertical-type nonvolatile memory device is provided in which differences between the sizes of channel holes in which channel structures are formed are reduced. The vertical-type nonvolatile memory device includes a substrate having channel hole recess regions in a surface thereof. Channel structures vertically protrude from the surface of the substrate on ones of the channel hole recess regions, and memory cell stacks including insulating and conductive layers are alternately stacked along sidewalls of the channel structures. A common source line extends along the surface of the substrate on other ones of the channel hole recess regions in a word line recess region, which separates adjacent memory cell stacks. Related fabrication methods are also discussed.

A semiconductor device includes; gate layers stacked on a substrate, a channel layer extending through the gate layers, a string select gate layer disposed on the channel layer and a string select channel layer extending through the string select gate layer to contact the channel layer. The string select channel layer includes a first portion below the string select gate layer including a first protruding region, a second portion extending through the string select gate layer, and a third portion above the string select gate layer including a second protruding region.

A semiconductor memory device includes a substrate, a plurality of first conductive layers, a second conductive layer, a first pillar, and a second pillar. The plurality of first conductive layers are stacked over the substrate in a first direction. The second conductive layer is disposed over the plurality of first conductive layers. The first pillar extends inside the plurality of first conductive layers in the first direction. The first pillar includes a first semiconductor portion including a first semiconductor of single-crystal. The second pillar extends inside the second conductive layer in the first direction. The second pillar includes an insulating portion serving as an axis including an insulator and a second semiconductor portion which is disposed on an outer circumference of the insulating portion in view of the first direction. The second semiconductor portion is in contact with the first semiconductor portion and includes a second semiconductor of poly-crystal.

A semiconductor memory device includes a substrate, a plurality of first conductive layers, a second conductive layer, a first pillar, and a second pillar. The plurality of first conductive layers are stacked over the substrate in a first direction. The second conductive layer is disposed over the plurality of first conductive layers. The first pillar extends inside the plurality of first conductive layers in the first direction. The first pillar includes a first semiconductor portion including a first semiconductor of single-crystal. The second pillar extends inside the second conductive layer in the first direction. The second pillar includes an insulating portion serving as an axis including an insulator and a second semiconductor portion which is disposed on an outer circumference of the insulating portion in view of the first direction. The second semiconductor portion is in contact with the first semiconductor portion and includes a second semiconductor of poly-crystal.

A semiconductor device includes: a stack structure including conductive patterns and stack insulating layers, which are alternately stacked; a channel structure penetrating the stack structure; a tunnel insulating layer surrounding the channel structure; a cell storage pattern surrounding the tunnel insulating layer; and a dummy storage pattern surrounding the tunnel insulating layer, the dummy storage pattern being spaced apart from the cell storage pattern. The conductive patterns include a select conductive pattern in contact with the tunnel insulating layer.

Embodiments of three-dimensional (3D) memory devices have a hydrogen blocking layer and fabrication methods thereof are disclosed. In an example, a method for form a 3D memory device is disclosed. An array of NAND memory strings each extending vertically above a first substrate are formed. A plurality of logic process-compatible devices are formed on a second substrate. The first substrate and the second substrate are bonded in a face-to-face manner. The logic process-compatible devices are above the array of NAND memory strings after the bonding. The second substrate is thinned to form a semiconductor layer above and in contact with the logic process-compatible devices.