A method for fabricating a semiconductor device may include: forming a gate dielectric material over a substrate; sequentially forming a carbon-undoped polysilicon layer and a carbon-doped polysilicon layer over the gate dielectric material; doping the carbon-doped polysilicon layer with a dopant; forming a columnar crystalline polysilicon layer over the carbon-doped polysilicon layer doped with the dopant; and performing annealing to activate the dopant.

Power switching devices include a semiconductor layer structure comprising an active region and an inactive region, the active region comprising a plurality of unit cells and the inactive region comprising a gate pad on the semiconductor layer structure and a gate bond pad on and electrically connected to the gate pad, an isolation layer between the gate pad and the gate bond pad, and a barrier layer between the gate pad and the isolation layer.

A method for fabricating a semiconductor device includes forming a trench in a substrate, forming a gate dielectric layer on a surface of the trench, forming a lower gate, which partially fills the trench, over the gate dielectric layer, forming a low work function layer over the lower gate, forming a spacer over the low work function layer, etching the low work function layer to be self-aligned with the spacer in order to form vertical gate on both upper edges of the lower gate, and forming an upper gate over the lower gate between inner sidewalls of the vertical gate.

A semiconductor device includes an insulating layer(IFL) on a semiconductor substrate(SUB), a conductive film (PL) on the insulating layer(IFL), an interlayer insulating film(IL) covering the conductive film(PL), a contact hole(CH1) in the interlayer insulating film(IL), the conductive film(PL) and the insulating layer (IFL), and a plug(PG1) embedded in the contact hole(CH1). A side surface of the interlayer insulating film(IL) is separated from a side surface of the conductive film(PL) to expose a part of an upper surface of the conductive film(PL), and a side surface of the insulating layer(IFL) is separated from the side surface of the conductive film(PL) to expose a part of a lower surface of the conductive film(PL). A distance(L1) from the lower surface of the conductive film(PL) to the bottom of the contact hole(CH1) is longer than a distance(L2) from the side surface of the conductive film(PL) to the side surface of the interlayer insulating film(IL).

A method for fabricating semiconductor device includes the steps of first forming a silicon layer on a substrate and then forming a metal silicon nitride layer on the silicon layer, in which the metal silicon nitride layer includes a bottom portion, a middle portion, and a top portion and a concentration of silicon in the top portion is greater than a concentration of silicon in the middle portion. Next, a conductive layer is formed on the metal silicon nitride layer and the conductive layer, the metal silicon nitride layer, and the silicon layer are patterned to form a gate structure.

A semiconductor device including a substrate including an active pattern; a gate electrode crossing the active pattern and extending in a first direction; a source/drain pattern on the active pattern and adjacent to a side of the gate electrode; and an active contact in a contact hole on the source/drain pattern, wherein the active contact includes a first contact in a lower region of the contact hole, the first contact including a barrier pattern and a conductive pattern; a diffusion barrier layer on the first contact; and a second contact on the diffusion barrier layer, and a top surface of the diffusion barrier layer is coplanar with a top surface of the barrier pattern of the first contact.

According to one embodiment, a semiconductor device includes an element region, an element isolation region adjacent to the element region, a gate insulating layer provided on an upper surface of the element region, and a gate electrode including a semiconductor layer, the semiconductor layer containing boron (B) and including a portion provided on the gate insulating layer, the element isolation region including an upper portion including an upper surface of the element isolation region and a lower portion including a lower surface of the element isolation region, and the upper portion of the element isolation region applying compressive stress to a portion of the element region, which is adjacent to the upper portion of the element isolation region.

A semiconductor device includes a substrate including a first active region, a second active region, and an isolation region positioned between the first active region and the second active region; and a gate layer crossing over the first active region, the second active region, and the isolation region, wherein the gate layer includes a first impurity doped portion overlapping with the first active region, a second impurity doped portion overlapping with the second active region, and a diffusion barrier portion positioned between the first impurity doped portion and the second impurity doped portion.

The present application provides a shielded gate trench (SGT) semiconductor apparatus and a manufacturing method thereof. The SGT semiconductor apparatus includes a heavily N-type doped semiconductor substrate; an N-type epitaxial layer formed on the semiconductor substrate; at least one trench structure formed on the epitaxial layer and accommodating at least one gate polysilicon layer, where the trench structure includes a shielding polysilicon layer and an inter-polysilicon oxide layer; a P-type doped body and an N-type doped source layer formed on the epitaxial layer; a contact region formed for the source and the shield polysilicon connected to a source metal and the gate polysilicon connected to a gate meal. The SGT semiconductor apparatus is surrounded by a shield polysilicon termination trench; the gate polysilicon connected to the gate metal bus line is made outside the active region across the shield polysilicon termination trench.

A semiconductor device may include a gate structure, first and second source/drain layers, first and second contact plugs, first and second conductive structures, and a third contact plug. The gate structure may be on a substrate. The first and second source/drain layers may be at upper portions, respectively, of the substrate on opposite sidewalls of the gate structure and adjacent thereto. The first and second contact plugs may be on the first and second source/drain layers, respectively, and each contact plugs may extend in a vertical direction. The first and second conductive structures may contact upper surfaces of the first and second contact plugs, respectively. The third contact plug may contact an upper surface of the second conductive structure. A height and a width of the second conductive structure may be greater than a height and a width of the first conductive structure.