A nonvolatile memory device includes a memory cell array including memory cells and a page buffer circuit. The page buffer circuit includes page buffer units and cache latches. The cache latches are spaced apart from the page buffer units in a first horizontal direction, and correspond to respective ones of the plurality of page buffer units. Each of the page buffer units includes a pass transistor connected to each sensing node and driven in response to a pass control signal. The page buffer circuit being configured to perform a data transfer operation, based on performing a first data output operation to output data, provided from a first portion of page buffer units, from a first portion of cache latches to a data input/output (I/O) line, the data transfer operation configured to dump sensed data from a second portion of page buffer units to a second portion of cache latches.

A semiconductor device includes a first substrate, a first insulating film provided on the first substrate, and a first plug provided in the first insulating film. The device further includes a first layer provided on the first insulating film and a first metal layer provided on the first plug in the first layer and electrically connected to the first plug. The device further includes a second metal layer including a first portion provided in the first layer and a second portion provided on the first layer and electrically connected to the first metal layer.

Disclosed are three-dimensional semiconductor memory devices and electronic systems including the same. The three-dimensional semiconductor memory device comprises a first structure and a second structure in contact with the first structure. Each of the first and second structures includes a substrate, a peripheral circuit region on the substrate, and a cell array region including a stack structure on the peripheral circuit region, a plurality of vertical structures that penetrate the stack structure, and a common source region in contact with the vertical structures. The stack structure is between the peripheral circuit region and the common source region. The common source regions of the first and second structures are connected with each other.

Provided is a nonvolatile memory device. The nonvolatile memory device includes a conductive plate, a barrier conductive film extending along a surface of the conductive plate, a mold structure including a plurality of gate electrodes sequentially stacked on the barrier conductive film, a channel hole penetrating the mold structure to expose the barrier conductive film, an impurity pattern being in contact with the barrier conductive film, and formed in the channel hole, and a semiconductor pattern formed in the channel hole, extending from the impurity pattern along a side surface of the channel hole, and intersecting the plurality of gate electrodes.

Embodiments of a three-dimensional (3D) memory device and fabrication methods are disclosed. In some embodiments, the 3D memory device includes a peripheral circuitry formed on a first substrate. The peripheral circuitry includes a plurality of peripheral devices on a first side of the first substrate, a first interconnect layer, and a deep-trench-isolation on a second side of the first substrate, wherein the first and second sides are opposite sides of the first substrate and the deep-trench-isolation is configured to provide electrical isolation between at least two neighboring peripheral devices. The 3D memory device also includes a memory array formed on a second substrate. The memory array includes at least one memory cell and a second interconnect layer, wherein the second interconnect layer of the memory array is bonded with the first interconnect layer of the peripheral circuitry, and the peripheral devices are electrically connected with the memory cells.

A semiconductor device includes an insulating structure; a plurality of horizontal layers vertically stacked and spaced apart from each other in the insulating structure; a conductive material pattern contacting the insulating structure; and a vertical structure penetrating through the plurality of horizontal layers and extending into the conductive material pattern in the insulating structure. Each of the plurality of horizontal layers comprises a conductive material, the vertical structure comprises a vertical portion and a protruding portion, the vertical portion of the vertical structure penetrates through the plurality of horizontal layers, the protruding portion of the vertical structure extends from the vertical portion into the conductive material pattern, a width of the vertical portion is greater than a width of the protruding portion, and a side surface of the protruding portion is in contact with the conductive material pattern.

In certain aspects, a three-dimensional (3D) memory device includes a first semiconductor structure and a second semiconductor structure bonded with the first semiconductor structure. The first semiconductor structure includes an array of NAND memory strings, a semiconductor layer in contact with source ends of the array of NAND memory strings, a non-conductive layer aligned with the semiconductor layer, and a contact structure in the non-conductive layer. The non-conductive layer electrically insulates the contact structure from the semiconductor layer. The second semiconductor structure includes a transistor.

A control circuit connected to non-volatile memory cells applies a programming signal to a plurality of the non-volatile memory cells in order to program the plurality of the non-volatile memory cells to a set of data states. The control circuit performs program verification for the non-volatile memory cells, including applying bit line voltages during program verification based on word line position and data state being verified.

Provided is a non-volatile memory device including a first structure including a first substrate; a peripheral circuit; a first insulation structure; a plurality of first bonding pads; and a first interconnect structure; a second structure, which includes a conductive etch stop layer; a common source line layer; a stacked structure including alternately stacked gate layers and interlayer insulation layers; a plurality of channel structures penetrating through a cell region of the stacked structure; a second insulation structure; a plurality of second bonding pads; and a second interconnect structure and bonded to the first structure; and a connection layer including a third insulation structure; an input/output via; and an input/output pad, wherein an interface between the second insulation structure and the third insulation structure is disposed at a vertical level between the top surface and the bottom surface of the conductive etch stop layer.

A semiconductor device includes a first substrate and a plurality of electrode layers above the first substrate and separated from each other in a first direction. The device includes a plurality of plugs provided on upper surfaces or lower surfaces of the plurality of electrode layers and a plurality of columnar portions in the plurality of electrode layers and extending in the first direction. A charge storage layer is between a semiconductor layer of the columnar portions and the electrode layers. A second substrate is provided above the plurality of electrode layers. A plurality of first transistors is provided on an upper surface of the first substrate and are electrically connected to the plurality of plugs. A plurality of second transistors is provided on a lower surface of the second substrate and are electrically connected to the plurality of columnar portions.