Abstract: A high-k metal gate device and manufacturing method thereof are provided in the present invention. The method uses a silicon material layer as a battier layer for the lower silicon nitride layer in the NMOS region and then performs an annealing process to turn the silicon material layer into a TiSiN interlayer of the PMOS region and a TiSiN layer of the NMOS region, respectively. TiSiN material can prevent subsequent upper metal atoms from diffusing downward and improve the stability of the metal gate device. Additionally, the silicon material remained on the surface of the NMOS region is subsequently removed, thereby eliminating differences of the thickness of the residual silicon material layer and fluctuations of the threshold voltage of the NMOS region resulted from the differences thereof and further improving the stability of the NMOS device.

Abstract: A high-k metal gate device and manufacturing method thereof are provided in the present invention. The method uses a silicon material layer as a battier layer for the lower silicon nitride layer in the NMOS region and then performs an annealing process to turn the silicon material layer into a TiSiN interlayer of the PMOS region and a TiSiN layer of the NMOS region, respectively. TiSiN material can prevent subsequent upper metal atoms from diffusing downward and improve the stability of the metal gate device. Additionally, the silicon material remained on the surface of the NMOS region is subsequently removed, thereby eliminating differences of the thickness of the residual silicon material layer and fluctuations of the threshold voltage of the NMOS region resulted from the differences thereof and further improving the stability of the NMOS device.

Abstract: The present invention relates to the manufacture of CMOS semiconductor device. This invention includes: Step S1, a layer of silicon oxide is deposited covering the surface of the polysilicon gates and the exposed upper surface of the silicon substrate, the silicon oxide layer is removed on the upper surface of the exposed silicon substrate, and then the barrier layer is formed at the surface of the polysilicon gates; Step S2, the ions are implanted into the exposed substrate, and then several doped silicon regions are formed in the silicon substrate; Step S3, the doped silicon regions are etched to form the trench of U-shape, then the barrier layer is removed. The present invention protects the polysilicon gate and the substrate during the process of forming the trench. The rate of etching is increased and the productivity is improved and it is possible to control the depth of the U-shaped trench.

Abstract: The present invention relates to the manufacture of CMOS semiconductor device. This invention includes: Step S1, a layer of silicon oxide is deposited covering the surface of the polysilicon gates and the exposed upper surface of the silicon substrate, the silicon oxide layer is removed on the upper surface of the exposed silicon substrate, and then the barrier layer is formed at the surface of the polysilicon gates; Step S2, the ions are implanted into the exposed substrate, and then several doped silicon regions are formed in the silicon substrate; Step S3, the doped silicon regions are etched to form the trench of U-shape, then the barrier layer is removed. The present invention protects the polysilicon gate and the substrate during the process of forming the trench. The rate of etching is increased and the productivity is improved and it is possible to control the depth of the U-shaped trench.

Abstract: The invention provides a method for producing silicon nanowire devices, including the following steps: growing SiNW on a substrate; depositing an amorphous carbon layer and dielectric anti-reflectivity coating orderly; removing part of dielectric anti-reflectivity coating and amorphous carbon layer above the SiNW through dry etching to expose the SiNW device area; depositing an oxide film on the surface of the above structure; forming a metal pad connected with the SiNW in the SiNW device area; depositing a passivation layer on the surface of the above structure; applying photolithography and etching technology to form contact holes on the metal pad and to remove the passivation layer, the oxide film and the dielectric anti-reflectivity coating above the SiNW outside the device area, stopping on the amorphous carbon layer; removing the amorphous carbon layer above the SiNW outside the device area through ashing process to expose the SiNW.

Abstract: The invention provides a method for producing silicon nanowire devices, including the following steps: growing SiNW on a substrate; depositing an amorphous carbon layer and dielectric anti-reflectivity coating orderly; removing part of dielectric anti-reflectivity coating and amorphous carbon layer above the SiNW through dry etching to expose the SiNW device area; depositing an oxide film on the surface of the above structure; forming a metal pad connected with the SiNW in the SiNW device area; depositing a passivation layer on the surface of the above structure; applying photolithography and etching technology to form contact holes on the metal pad and to remove the passivation layer, the oxide film and the dielectric anti-reflectivity coating above the SiNW outside the device area, stopping on the amorphous carbon layer; removing the amorphous carbon layer above the SiNW outside the device area through ashing process to expose the SiNW.