Abstract: The present disclosure provides a surface mount data conversion method, system, medium and apparatus based on a component three-dimensional database. The surface mount data conversion method based on a component three-dimensional database includes: creating a component 3D database required in a circuit board designing stage and creating a production process template library required in a circuit board production stage; and performing data conversion on the component 3D database and the production process template library to generate a component image library for use in the production stage. The present disclosure can avoid repeated work, achieve real-time update and match of production data, and reduce the error rate caused by the production data during circuit board production.

Abstract: A super junction MOSFET device, including: a substrate having a first conductive type; a buffer layer having the first conductive type and disposed on the substrate; a super junction structure disposed on the buffer layer and including multiple first conductive type pillars and multiple second conductive type pillars alternately arranged in a transverse direction, several second conductive type pillars being partially and/or wholly displaced to provide two or more different transverse dimensions for the first conductive type pillars; a body region having the second conductive type and disposed on a top of the second conductive type pillar; a source structure located within the body region and including a source region having the first conductive type and an ohmic contact region having the second conductive type which contacts with the source region; and a gate structure in contact with the first conductive type pillar and the source structure.

Abstract: A semiconductor device comprises a drift region (100), a body region (110), a first doped region (111) and a second doped region (112)); a first trench penetrates the first doped region (111), the body region (110) extends into the drift region (100); an extension region (150) having an opposite conductivity type to the drift region (100) and surrounding the bottom wall of the first trench; where the first trench is filled with a first conductive structure (141) and a second conductive structure (142); a dielectric layer (130) formed between the second conductive structure (142) and the inner wall of the first trench, as well as between the first conductive structure (141) and the inner wall of the first trench; a second trench penetrating the first doped region (111) and the body region (110), and a dielectric layer (130) located between the third conductive structure (143) and the second trench (122).

Abstract: A preparation method for semiconductor device, comprising: forming a body region (110) in the drift region (100), forming a first doped region (111) and a second doped region (112) in the body region (110); forming a first trench (171) penetrating the first doped region (111) and the body region (110) and extending to the drift region (100); forming an extension region (150) with a conductivity type opposite to that of the drift region (100) and surrounding the bottom wall of the first trench (171); filling the first trench (171) with a dielectric layer (130) formed on the sidewall of the trench, a first conductive structure (141) located at the bottom of the trench and a second conductive structure (142) located at the top of the trench; forming a second trench (172) penetrating the body region (110) and extending into the drift region (100); filling the second trench (172) with a third conductive structure (143) and a dielectric layer (130) formed on the inner wall of the trench.

Abstract: A semiconductor device comprises a drift region (100), a body region (110), a first doped region (111) and a second doped region (112)); a first trench penetrates the first doped region (111), the body region (110) extends into the drift region (100); an extension region (150) having an opposite conductivity type to the drift region (100) and surrounding the bottom wall of the first trench; where the first trench is filled with a first conductive structure (141) and a second conductive structure (142); a dielectric layer (130) formed between the second conductive structure (142) and the inner wall of the first trench, as well as between the first conductive structure (141) and the inner wall of the first trench; a second trench penetrating the first doped region (111) and the body region (110), and a dielectric layer (130) located between the third conductive structure (143) and the second trench (122).

Abstract: The present disclosure provides a trench field effect transistor and a manufacturing method. The manufacturing method includes: providing a semiconductor substrate, forming an epitaxial layer, a first trench, a second trench, a first gate dielectric layer, a first gate structure, a second gate dielectric layer, a second gate structure, and a body region, forming a source implantation mask, performing ion implantation based on the source implantation mask to form a source, and forming a source electrode structure. Self-aligned source implantation is implemented by designing a source implantation mask, and a body region lead-out region is formed while forming a source, so that the source and the body region are directly led out. The present disclosure uses a self-alignment technique to further reduce a cell dimension, and enables equal-potential electrical lead-out of the source and the body region without providing a source contact hole.

Abstract: A preparation method for semiconductor device, comprising: forming a body region (110) in the drift region (100), forming a first doped region (111) and a second doped region (112) in the body region (110); forming a first trench (171) penetrating the first doped region (111) and the body region (110) and extending to the drift region (100); forming an extension region (150) with a conductivity type opposite to that of the drift region (100) and surrounding the bottom wall of the first trench (171); filling the first trench (171) with a dielectric layer (130) formed on the sidewall of the trench, a first conductive structure (141) located at the bottom of the trench and a second conductive structure (142) located at the top of the trench; forming a second trench (172) penetrating the body region (110) and extending into the drift region (100); filling the second trench (172) with a third conductive structure (143) and a dielectric layer (130) formed on the inner wall of the trench.

Abstract: The present disclosure provides a trench field effect transistor structure and a manufacturing method thereof. The manufacturing method includes: providing a substrate (100), forming an epitaxial layer (101), forming a device trench (102) in the epitaxial layer, and forming a shielding dielectric layer (107), a shielding gate layer (105), a first isolation dielectric layer (108), a gate dielectric layer (109), a gate layer (110), a second isolation dielectric layer (112), a body region (114), a source (115), a source contact hole (118), a source electrode structure (122), and a drain electrode structure (123). During manufacturing of a trench field effect transistor structure, a self-alignment process is adopted in a manufacturing process, so that a cell pitch is not limited by an exposure capability and alignment accuracy of a lithography machine, to further reduce the cell pitch of the device, improve a cell density, and reduce a device channel resistance.

Abstract: The present disclosure provides a trench field effect transistor and a manufacturing method. The manufacturing method includes: providing a semiconductor substrate, forming an epitaxial layer, a first trench, a second trench, a first gate dielectric layer, a first gate structure, a second gate dielectric layer, a second gate structure, and a body region, forming a source implantation mask, performing ion implantation based on the source implantation mask to form a source, and forming a source electrode structure. Self-aligned source implantation is implemented by designing a source implantation mask, and a body region lead-out region is formed while forming a source, so that the source and the body region are directly led out. The present disclosure uses a self-alignment technique to further reduce a cell dimension, and enables equal-potential electrical lead-out of the source and the body region without providing a source contact hole.

Abstract: A self-balancing super junction structure and a preparation method thereof. The method includes: forming an initial epitaxial layer on a surface of a substrate of a first doping type; respectively forming an implantation region of the first doping type and an implantation region of a second doping type in the initial epitaxial layer; forming an intrinsic epitaxial layer on the surface of the initial epitaxial layer; respectively forming an implantation region of the first doping type and an implantation region of the second doping type in the intrinsic epitaxial layer; and repeating the steps to form a structure with stacked epitaxial layers, and then performing thermal diffusion treatment to form a self-balancing super junction structure. Ions of the first doping type and ions of the second doping type in a same layer of the epitaxial layer stack structure are implanted after a same lithography step.