A memory device includes a memory array, a circuit structure, a bonding structure between the memory array and the circuit structure, and a shielding structure between the memory array and the circuit structure and surrounding the bonding structure. The bonding structure includes a first bonding pattern and a second bonding pattern. The circuit structure is electrically connected with the memory array through the bonding structure. The shielding structure includes a third bonding pattern and a fourth bonding pattern. The first bonding pattern is in contact with the second bonding pattern at a first interface between the first bonding pattern and the second bonding pattern. The third bonding pattern is in contact with the fourth bonding pattern at a second interface between the third bonding pattern and the fourth bonding pattern.

A three-dimensional flash memory is provided, and technique to suppress interference caused by an inter-cell insulation layer in a vertical cell and to form a stable vertical channel layer, a technique to reduce a length of wire than a conventional three-dimensional flash memory for overcoming problems of deterioration of chip characteristics such as operation speed and power consumption and difficulty of wiring technique in the manufacturing process, and a technique to improve horizontal density of channel layers and ONO layers are proposed.

An integrated circuit device includes: a lower memory stack including a plurality of lower word lines located on a substrate, an upper memory stack located on the lower memory stack and including a plurality of upper word lines, at least one first lower interconnection layer extending in a horizontal direction at a first vertical level between the lower memory stack and the upper memory stack, and configured to be electrically connected to at least one lower word line selected from the plurality of lower word lines, a separate insulating film covering at least one first lower interconnection layer, and at least one first upper interconnection layer extending in the horizontal direction at a second vertical level higher than the upper memory stack, and configured to be electrically connected to at least one upper word line selected from the upper word lines.

A semiconductor device includes a cell region and a peripheral circuit region. The cell region includes gate electrode layers stacked on a substrate, channel structures extending in a first direction, extending through the gate electrode layers, and connected to the substrate, and bit lines extending in a second direction and connected to the channel structures above the gate electrode layers. The peripheral circuit region includes page buffers connected to the bit lines. Each page buffer includes a first and second elements adjacent to each other in the second direction and sharing a common active region between a first gate structure of the first element and a second gate structure of the second element in the second direction. Boundaries of the common active region include an oblique boundary extending in an oblique direction forming an angle between 0 and 90 degrees with the second direction.

A bonded assembly includes a first semiconductor die and a second semiconductor die that are bonded to each other by dielectric-to-dielectric bonding. First conductive via structures vertically extend through the second semiconductor die and a respective subset of the first dielectric material layers in the first semiconductor die, and contact a respective first metal interconnect structure in the first semiconductor die. Second conductive via structures vertically extend through a second substrate and a respective subset of the second dielectric material layers in the second semiconductor die, and contacting a respective second metal interconnect structure in the second semiconductor die. Redistribution metal interconnect structures located over a backside surface of the second substrate electrically connect the first conductive via structures and the second conductive via structures, and provide electrical interconnection between the first semiconductor die and the second semiconductor die.

A peripheral circuit structure may include peripheral circuits and peripheral circuit lines on a semiconductor substrate, a semiconductor layer including cell array and connection regions on the peripheral circuit structure, a stack including electrodes stacked on the semiconductor layer having a stepwise structure on the connection region, and a planarization insulating layer covering the stack, vertical structures on the cell array region penetrating the stack, including a data storage pattern, a dam group including insulating dams on the connection region penetrating the stack, penetration plugs penetrating the insulating dams and connected to respective peripheral circuit lines, the dam group including a first insulating dam farthest from the cell array region, the first insulating dam including first and second sidewall portions spaced apart, a difference between upper and lower thicknesses of the second sidewall portion of the first insulating dam is larger than that of the first sidewall portion.

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.

Provided is a three-dimensional storage device using wafer-to-wafer bonding. A storage device includes a first chip including a first substrate and a peripheral circuit region including a first control logic circuit configured to control operation modes of the non-volatile memory device and a second chip including a second substrate and three-dimensional arrays of non-volatile memory cells. The second chip may be vertically stacked on the first chip so that a first surface of the first substrate faces a first surface of the second substrate, and a second control logic circuit is configured to control operation conditions of the non-volatile memory device and is arranged on a second surface of the second substrate, the second surface of the second substrate being opposite to the first surface of the second substrate of the second chip.

A semiconductor device includes a lower insulating film that includes a first and second trenches on a substrate, a first wiring in the first trench, a second wiring in the second trench, a capping insulating film including an insulating recess portion and an insulating liner portion, an upper insulating film on the capping insulating film, and an upper contact that penetrates the capping insulating film and connects to the first wiring, The insulating recess portion is in the second trench and the insulating liner portion extends along an upper surface of the lower insulating film. The upper contact includes a contact recess portion in the first trench, an extended portion connected to the contact recess portion, and a plug portion connected to the extended portion inside the upper insulating film. A width of the extended portion is greater than a width of the plug portion.

A semiconductor device includes a memory cell array including a plurality of memory blocks, each of the plurality of memory blocks including select transistors and memory cells; pass transistors configured to provide select signals to select lines connected to a selected memory block; and ground transistors configured to supply a first voltage to select lines connected to unselected memory blocks. The ground transistors include at least one common gate structure, at least one common active region, and individual active regions, and each of the common gate structure and the common active region are shared by two or more ground transistors, among the ground transistors. The common gate structure is between the common active region and the individual active regions, and includes a first region extending in a first direction and a second region extending in a second direction, intersecting the first direction.