A photolithographic exposure method for a memory. In a photolithographic process for making a memory, when exposure is performed by using a mask, regions with different exposure dimension requirements on the memory are divided into different exposure groups. Regions with the same exposure resolution requirement are divided into the same group. Different exposure modes of exposure that are capable of correspondingly satisfying resolution requirements of each group are performed to different groups during exposure. During exposure, different illumination modes are adopted to perform exposure. Firstly, a first exposure mode is adopted to perform exposure to a memory array cell exposure group, then a wafer is kept stationary on a supporting platform, and then a second exposure mode is adopted to perform exposure to the other structure exposure group; after the exposure of all groups is completed, one-step development is performed to complete pattern transfer.

A semiconductor device includes a stack structure, first separation patterns passing through the stack structure, a second separation pattern passing through at least a portion of the stack structure between the first separation patterns, and a cutting channel structure passing through the stack structure and having an end portion partially cut by the second separation pattern. A channel layer of the cutting channel structure has a ring shape cut by the second separation pattern to have end portions of the channel layer which are spaced apart from each other.

A semiconductor memory device includes a cell unit including a stack structure and a channel structure penetrating through the stack structure, the stack structure including at least one string selection gate and a plurality of cell gates, cell separation structures separating the cell unit in a first direction, and gate cutting structures defining regions within the cell unit between adjacent cell separation structures. The cell unit includes a first region defined between a first cell separation structure and a first gate cutting structure and a second region defined between the first gate cutting structure and a second gate cutting structure. A ratio of a region of the at least one string selection gate that is occupied by a conductive material in the second region is greater than a ratio of a region of at least one cell gate that is occupied by the conductive material in the second region.

A semiconductor device includes a substrate having a first region and a second region, gate electrodes stacked and spaced apart from each other in a first direction perpendicular to an upper surface of the second substrate, and extending by different lengths in a second direction on the second region to have pad regions in which upper surfaces thereof are exposed, channel structures penetrating the gate electrodes, extending in the first direction, and respectively including a channel layer, on the first region, contact plugs penetrating the pad regions of the gate electrodes and extending in the first direction, and contact insulating layers surrounding the contact plugs. The gate electrodes have side surfaces protruding further toward the contact plugs in the pad regions than ones of the gate electrodes therebelow.

A semiconductor device and a data storage system including the same are provided. The semiconductor device including a plate layer, a pattern structure on the plate layer, an upper pattern layer on the pattern structure, an upper structure including a stack structure and a capping insulating structure covering at least a portion of the stack structure, the stack structure including interlayer insulating layers and gate layers alternately stacked on each other, and separation structures and vertical memory structures penetrating through the upper structure, the upper pattern layer, and the pattern structure, and extending into the plate layer may be provided.

A data storage device includes a substrate including a number of contact pads and a number of passive component packages coupled to the contact pads. The data storage device further includes a memory controller coupled to the substrate, and one or more NAND die stacks coupled to the substrate and in electrical communication with the memory controller. One or more of the passive component packages include a first passive component, a second passive component electrically connected to the first passive component, and a first terminal coupled to the first passive component. The passive component packages further include a second terminal coupled to the second passive component, and a third terminal coupled to a common node of the first passive component and the second passive component.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers, memory openings vertically extending through the alternating stack, and memory opening fill structures located within the memory openings. Each of the electrically conductive layers includes a metallic fill material layer and a plurality of vertical tubular metallic liners laterally surrounding a respective one of the memory opening fill structures and located between the metallic fill material layer and a respective one of the memory opening fill structures. The tubular metallic liners may be formed by selective metal or metal oxide deposition, or by conversion of surface portions of the metallic fill material layers into metallic compound material portions by nitridation, oxidation, or incorporation of boron atoms.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers, memory openings vertically extending through the alternating stack, and memory opening fill structures located within the memory openings. Each of the electrically conductive layers includes a metallic fill material layer and a plurality of vertical tubular metallic liners laterally surrounding a respective one of the memory opening fill structures and located between the metallic fill material layer and a respective one of the memory opening fill structures. The tubular metallic liners may be formed by selective metal or metal oxide deposition, or by conversion of surface portions of the metallic fill material layers into metallic compound material portions by nitridation, oxidation, or incorporation of boron atoms.

A bonded assembly includes a memory die that is bonded to a logic die. The memory die includes a three-dimensional memory array located on a memory-side substrate, memory-side dielectric material layers located on the three-dimensional memory array and embedding memory-side metal interconnect structures and memory-side bonding pads, a backside peripheral circuit located on a backside surface of the memory-side substrate, and backside dielectric material layers located on a backside of the memory-side substrate and embedding backside metal interconnect structures. The logic die includes a logic-side peripheral circuit located on a logic-side substrate, and logic-side dielectric material layers located between the logic-side substrate and the memory die and embedding logic-side metal interconnect structures and logic-side bonding pads that are bonded to a respective one of the memory-side bonding pads.

Memory cells having a first dielectric between a charge storage material and a semiconductor, conductive nanodots between the charge storage material and a control gate, and a second dielectric between the control gate and the conductive nanodots.