A semiconductor storage device includes a memory cell unit which includes memory cell arrays including a plurality of memory cells; a peripheral circuit which performs voltage transmission control including a write operation, a read operation, and an erasing operation with respect to the memory cell unit; and signal lines which connect the peripheral circuit to the memory cell unit, and at least a portion of the signal lines is formed in a non-facing region, the non-facing region being a region where the memory cell unit does not face the peripheral circuit, the non-facing region being in a peripheral region formed around a periphery of the memory cell arrays of the memory cell unit.

A first tier structure including a first alternating stack of first insulating layers and first sacrificial material layers is formed over a substrate. First support pillar structures are formed through the first tier structure. A second tier structure including a second alternating stack of second insulating layers and second sacrificial material layers is formed over the first tier structure. Memory stack structures and second support pillar structures are formed through the second tier structure. The first and second sacrificial material layers are replaced with first and second electrically conductive layers while the first support pillar structures, the second support pillar structures, and the memory stack structures provide structural support to the first and second insulating layers. By limiting the spatial extent of the first support pillar structures within the first tier structure, electrical short to backside contact via structures can be reduced.

A method of manufacturing a non-volatile memory is described. A substrate including a first region and a second region located at periphery of the first region is provided. A plurality of stacked structures are formed on the first region of the substrate. A wall structure is formed on the second region of the substrate. A conductive layer is formed over the substrate. A bottom anti-reflective coating is formed over the conductive layer. The bottom anti-reflective coating and the conductive layer are etched back. The conductive layer is patterned.

Provided is a stable manufacturing method for a semiconductor device. In the manufacturing method for a semiconductor device, first, fins with an equal width are formed in each of a memory cell portion and a logic portion of a semiconductor substrate. Then, the fins in the logic portion are etched with the fins in the memory cell covered with a mask film, thereby fabricating fins in the logic portion, each of which is narrower than the fin formed in the memory cell portion.

A method of manufacturing an embedded flash memory device is provided. A pair of gate stacks are formed spaced over a semiconductor substrate, and including floating gates and control gates over the floating gates. A common gate layer is formed over the gate stacks and the semiconductor substrate, and lining sidewalls of the gate stacks. A first etch is performed into the common gate layer to recess an upper surface of the common gate layer to below upper surfaces respectively of the gate stacks, and to form an erase gate between the gate stacks. Hard masks are respectively formed over the erase gate, a word line region of the common gate layer, and a logic gate region of the common gate layer. A second etch is performed into the common gate layer with the hard masks in place to concurrently form a word line and a logic gate.

Apparatuses and methods have been disclosed. One such apparatus includes strings of memory cells formed on a topside of a substrate. Support circuitry is formed on the backside of the substrate and coupled to the strings of memory cells through vertical interconnects in the substrate. The vertical interconnects can be transistors, such as surround substrate transistors and/or surround gate transistors.

In a method of manufacturing a semiconductor device, a memory cell structure covered by a protective layer is formed in a memory cell area of a substrate. A mask pattern is formed. The mask pattern has an opening over a first circuit area, while the memory cell area and a second circuit area are covered by the mask pattern. The substrate in the first circuit area is recessed, while the memory cell area and the second circuit area are protected. A first field effect transistor (FET) having a first gate dielectric layer is formed in the first circuit area over the recessed substrate and a second FET having a second gate dielectric layer is formed in the second circuit area over the substrate as viewed in cross section.

A semiconductor memory device includes a substrate, a plurality of insulating layers and wiring layers that are alternately formed, and a plurality of first layers and second layers that are alternately formed. The substrate has a memory region extending in first and second directions along a surface of the substrate, a step region adjacent to the memory region in the first direction, and a peripheral region adjacent to the memory region and the step region in the second direction. The insulating layers and the wiring layers are formed on the memory region and the step region. The first and second layers are formed on the peripheral region. Each of the first layers is formed on a same level as and in contact with one of the insulating layers, and each of the second layers is formed on a same level as and in contact with one of the wiring layers.

Disposed are a semiconductor structure, a manufacturing method thereof and a flash memory. The semiconductor structure includes a substrate, first isolation structures, a gate structure and an oxide layer. The first isolation structures define a first active area in a peripheral region of the substrate. The oxide layer is disposed on the substrate in the first active area and covered by the first isolation structures. The oxide layer and the first isolation structures define an opening exposing the substrate. The gate structure is disposed on the substrate in the first active area and includes a gate dielectric layer disposed in the opening and a gate disposed on the gate dielectric layer. The oxide layer is located around the gate dielectric layer. The width of the bottom surface of the gate is less than that of the top surface of the first active area.

Various embodiments comprise apparatuses and methods including a memory array having alternating levels of semiconductor materials and dielectric material with strings of memory cells formed on the alternating levels. One such apparatus includes a memory array formed substantially within a cavity of a substrate. Peripheral circuitry can be formed adjacent to a surface of the substrate and adjacent to the memory array. Additional apparatuses and methods are described.