A semiconductor device includes a substrate and a semiconductor layer. The substrate includes a planar portion and a plurality of pillars on a periphery of the planar portion. The pillars are shaped as rectangular columns, and corners of two of the pillars at the same side of the planar portion are aligned in a horizontal direction or a direction perpendicular to the horizontal direction. The semiconductor layer is disposed over the planar portion and between the pillars.

Disclosed are semiconductor devices and methods of manufacturing the same. The method comprises alternately stacking a plurality of dielectric layers and a plurality of first semiconductor layers to form a mold structure on a substrate, forming a hole penetrating the mold structure, forming on the substrate a second semiconductor layer filling the hole, and irradiating a laser onto the second semiconductor layer.

A method of producing a polycrystalline silicon TFT includes forming nickel patterns on a substrate, forming a phosphorus doped silicon layer over the substrate and nickel patterns, and forming an intrinsic silicon layer on the phosphorus doped silicon layer. Alternatively, the intrinsic silicon layer can be formed on the substrate, the phosphorus doped silicon layer on the intrinsic silicon layer, and the nickel patterns on the phosphorus doped silicon layer. The structure is annealed to crystallize the phosphorus doped silicon and intrinsic silicon layers. A method of forming a crystalline silicon layer of a TFT device includes forming a first silicon film, forming a phosphorus doped silicon film on the first silicon film, forming a nickel film on the phosphorus doped silicon film, and annealing the structure to crystallize the phosphorus doped silicon and first silicon films. The first silicon and phosphorous doped silicon films are amorphous at formation.

A method of producing a reduced-defect density crystalline silicon film includes forming a Six1Ge1-x1 film on a substrate, forming a Six2Ge1-x2 film on the Six1Ge1-x1 film, forming a silicon film on the Six2Ge1-x2 film, and annealing to crystallize the Six1Ge1-x1, Six2Ge1-x2, and silicon films. The values of x1 and x2 are between zero and one. The Six1Ge1-x1 and Six2Ge1-x2 films are amorphous at formation, having a first thermal budget and a second thermal budget, respectively, for crystallization, the second thermal budget lower than the first thermal budget, the Six2Ge1-x2 film spaced apart from the substrate by the Six1Ge1-x1 film. A crystalline silicon TFT device includes a substrate, a crystallized Six1Ge1-x1 layer on the substrate, a crystallized Six2Ge1-x2 layer on the crystallized Six1Ge1-x1 layer, a crystallized silicon layer on the Six2Ge1-x2 layer, a gate insulator layer on the crystallized silicon layer, and a gate electrode on the gate insulator layer.

A method of forming a crystallized semiconductor layer includes forming an insulating crystallization inducing layer on a base substrate; forming a semiconductor material layer on a side of the insulating crystallization inducing layer away from the base substrate by depositing a semiconductor material on the insulating crystallization inducing layer, the semiconductor material being deposited at a deposition temperature that induces crystallization of the semiconductor material; forming an alloy crystallization inducing layer including an alloy on a side of the semiconductor material layer away from the insulating crystallization inducing layer; and annealing the alloy crystallization inducing layer to further induce crystallization of the semiconductor material to form the crystallized semiconductor layer. Annealing the alloy crystallization inducing layer is performed to enrich a relatively more conductive element of the alloy to a side away from the base substrate, thereby forming an annealed crystallization inducing layer.

A thin film transistor includes an active layer including a first portion having a first thickness and a second portion having a second thickness greater than the first thickness, a capping layer filling a thickness difference between the first portion and the second portion and arranged on the first portion, a gate insulating layer arranged on the capping layer, a gate electrode on the active layer, wherein the gate insulating layer and the capping layer are disposed between the gate electrode and the active layer, and a source electrode and a drain electrode connected to the active layer.

In one embodiment, a semiconductor storage device includes a stacked body in which a plurality of conducting layers are stacked through a plurality of insulating layers in a first direction, a semiconductor layer penetrating the stacked body, extending in the first direction and including metal atoms, and a memory film including a first insulator, a charge storage layer and a second insulator that are provided between the stacked body and the semiconductor layer. The semiconductor layer surrounds a third insulator penetrating the stacked body and extending in the first direction, and at least one crystal grain in the semiconductor layer has a shape surrounding the third insulator.

A method of manufacturing a semiconductor nanowire semiconductor device is described. The method includes forming an amorphous channel material layer on a substrate, patterning the channel material layer to form semiconductor nanowires extending in a lateral direction on the substrate, and forming a cover layer covering an upper of the semiconductor nanowire. The cover layer and the nanowire are patterned to form a trench exposing a side surface of an one end of the semiconductor nanowire and a catalyst material layer is formed in contact with a side surface of the semiconductor nanowire, and metal induced crystallization (MIC) by heat treatment is performed to crystallize the semiconductor nanowire in a length direction of the nanowire from the one end of the semiconductor nanowire in contact with the catalyst material.

Provided is a method of manufacturing a semiconductor device, the method including: forming an insulating layer on a substrate; forming a trench, which extends in a first direction parallel with the plane of the substrate, to a preset depth in the insulating layer in a second direction perpendicular to the plane of the substrate; forming a plurality of amorphous silicon strips, which extend from the inside of the trench in the second direction intersecting with the first direction, in parallel in a first direction; forming a spacer on a side of the amorphous silicon strip by using an insulating material layer; and crystallizing the amorphous silicon strip by heat treatment, wherein crystal nucleation sites are formed in the amorphous silicon layer in the trench, and a polycrystalline silicon layer is formed by lateral grain growth in a longitudinal direction of the amorphous silicon strip from the crystal nucleation site.

Provided is a method of manufacturing a semiconductor device, the method including: forming a buffer layer of an insulating layer on a substrate; a seed layer formation operation of forming, on the buffer layer, a seed layer of at least one selected from the group consisting of NiCxOy, NiNxOy, NiCxNyOz, NiCxOy:H, NiNxOy:H, NiCxNyOz:H, NixSiy, and NixGey; a silicon layer formation operation of forming an amorphous silicon layer on the seed layer; and a crystallization operation of crystallizing the amorphous silicon layer by a catalytic action of Ni by thermally treating the amorphous silicon layer.