The degree of integration of a semiconductor device is enhanced and the storage capacity per unit area is increased. The semiconductor device includes a first transistor provided in a semiconductor substrate and a second transistor provided over the first transistor. In addition, an upper portion of a semiconductor layer of the second transistor is in contact with a wiring, and a lower portion thereof is in contact with a gate electrode of the first transistor. With such a structure, the wiring and the gate electrode of the first transistor can serve as a source electrode and a drain electrode of the second transistor, respectively. Accordingly, the area occupied by the semiconductor device can be reduced.

A method of reducing warp imparted to a silicon wafer having a (110) plane orientation and a <111> notch orientation by anisotropic film stress of a multilayer film that is to be formed on a surface of the silicon wafer, that includes forming the multilayer film on a surface of the silicon wafer in an orientation so that a direction in which the warp of the wafer will be greatest coincides with a direction in which Young's modulus of a crystal orientation of the silicon wafer is greatest. Also, a method of reducing warp imparted to a silicon wafer having a (111) plane orientation by isotropic film stress of a multilayer film to be formed on a surface of the silicon wafer, that includes, prior to forming the multilayer film, causing the silicon wafer to have an oxygen concentration of 8.0×10.sup.17 atoms/cm.sup.3 or more (ASTM F-121, 1979).

A flash memory device and its manufacturing method, which is related to semiconductor techniques. The flash memory device comprises: a substrate; and a memory unit on the substrate, comprising: a channel structure on the substrate, wherein the channel structure comprise, in an order from inner to outer of the channel structure, a channel layer, an insulation layer wrapped around the channel layer, and a charge capture layer wrapped around the insulation layer; a plurality of gate structures wrapped around the channel structure and arranged along a symmetry axis of the channel structure, wherein there exist cavities between neighboring gate structures; a support structure supporting the gate structures; and a plurality of gate contact components each contacting a gate structure. The cavities between neighboring gate structures lower the parasitic capacitance, reduce inter-gate interference, and suppress the influence from writing or erasing operations of nearby memory units.

A method for forming a semiconductor device includes forming a metal layer and a spacer adjacent to the metal layer. The spacer includes a composite-dielectric layer including a composite-dielectric material. A composition of the composite-dielectric material is a mixture of a composition of a first dielectric material and a composition of a second dielectric material different from the first dielectric material.

A semiconductor device structure that comprises tiers of alternating dielectric levels and conductive levels and a carbon-doped silicon nitride over the tiers of the staircase structure. The carbon-doped silicon nitride excludes silicon carbon nitride. A method of forming the semiconductor device structure comprises forming stairs in a staircase structure comprising alternating dielectric levels and conductive levels. A carbon-doped silicon nitride is formed over the stairs, an oxide material is formed over the carbon-doped silicon nitride, and openings are formed in the oxide material. The openings extend to the carbon-doped silicon nitride. The carbon-doped silicon nitride is removed to extend the openings into the conductive levels of the staircase structure. Additional methods are disclosed.

A three-dimensional memory includes a stack structure, a dummy structure and a gate line slit. The stack structure includes gate line layers and isolation layers stacked alternatively in the vertical direction. The dummy structure includes a first dummy section and a second dummy section. The gate line slit has one end extending into a gap formed by at least one of the first dummy section or the second dummy section. At least one of the first dummy section and the second dummy section partially overlaps a projection of the gate line slit onto the horizontal plane to realize connection between the dummy structure and the gate line slit.

A non-volatile memory device includes a plurality of memory blocks and a dummy block configured to form a pool capacitor for suppressing power noise. The dummy block includes a substrate, a conductor region in the substrate, and an alternating dummy layer stack on the conductor region. The alternating dummy layer stack includes multiple conductive layers and multiple dielectric layers alternately laminated on one another.

A semiconductor storage device includes first wiring layers stacked along a first direction, a first pillar including a first semiconductor layer and extending along the first direction through the first wiring layers, a second wiring layer disposed above the first pillar in the first direction and extending along a second direction perpendicular to the first direction, a semiconductor-containing layer including a first portion disposed on an upper end of the first pillar in the first direction, a second portion contacting the first portion and formed along the second wiring layer, and a third portion contacting an upper end of the second portion and extending along a third direction perpendicular to the first direction and crossing the second direction, and a first insulating layer between each of the first and second portions of the semiconductor-containing layer and the second wiring layer. An upper surface of the third portion contains a metal.

According to one embodiment, a semiconductor memory device includes a stacked layer body including conductive layers stacked to be apart from each other in a first direction, and including a stair-like end with rising parts and terrace parts, wherein successive first conductive layers including an uppermost conductive layer function as select gate lines for a NAND string, and a first contact connected to the uppermost conductive layer provided to correspond to a first rising part which is an uppermost one of the rising parts. The first contact passes through the uppermost conductive layer to be further connected to a first conductive layer adjacent to the uppermost conductive layer.

According to one embodiment, a semiconductor memory device includes a stacked layer body including conductive and insulating layers alternately stacked in a first direction, partition structures each extending in first and second directions in the stacked layer body, and an intermediate structure extending from an upper end and terminating at a position between upper and lower ends of the stacked layer body between adjacent partition structures. The partition structures include a first partition structure including first and second portions arranged in the second direction, the first portion extends from the upper end to the lower end, and the second portion is located between adjacent first portions, extends from the upper end and terminates at the position between the upper and lower ends.