Abstract: Disclosed is a method for manufacturing an isolation structure for LDMOS, the method comprising: forming a first groove on the surface of a wafer; filling the first groove with silicon oxide; removing part of the surface of the silicon oxide within the first groove by means of etching; forming a silicon oxide corner structure at the corner of the top of the first groove by means of thermal oxidation; depositing a nitrogen-containing compound on the surface of the wafer to cover the surface of the silicon oxide within the first groove and the surface of the silicon oxide corner structure; dry-etching the nitrogen-containing compound to remove the nitrogen-containing compound from the surface of the silicon oxide within the first groove, and thereby forming a nitrogen-containing compound side wall residue; with the nitrogen-containing compound side wall residue as a mask, continuing to etch downwards to form a second groove; forming a silicon oxide layer on the side wall and the bottom of the second groove; rem

Abstract: A method for manufacturing a trench isolation structure comprising forming a shallow trench having a wider upper section and a narrower lower section in a wafer surface, removing part of the silicon oxide by etching, forming a silicon oxide corner structure at a corner at a top corner of the shallow trench by thermal oxidation, depositing silicon nitride on the wafer surface to cover surfaces of the shallow trench silicon oxide and the silicon oxide corner structure, dry etching the silicon nitride on the shallow trench silicon oxide surface thereby forming masking silicon nitride residues extending into the trench, etching downwards to form a deep trench, forming silicon oxide layers on a side wall and the bottom of the deep trench, depositing polycrystalline silicon in the shallow and deep trenches, removing the silicon nitride, and forming silicon oxide in the shallow trench to cover the polycrystalline silicon.

Abstract: A semiconductor device for enhancing electrostatic discharge (ESD) protection and a layout structure thereof are provided. An ESD protection device and a protected device (300) with a small feature linewidth are located on the same well region. The device (300) with the small feature linewidth is located at a middle portion. The ESD protection device is disposed at both sides of the device (300) with the small feature linewidth.

Abstract: A gate structure of a semiconductor device, includes: a trench gate and a planar gate including a plurality of polysilicon structures (406) separated from each other; the gate structure of the semiconductor device further includes a well region (503) being adjacent to the trench gate and being disposed under the planar gate; a first conduction type doped region (504) being disposed in the well region (503) and including a plurality of regions separated from each other, wherein each region is disposed under adjacent polysilicon structures (406), and respective regions are electrically connected to the planar gate; and a source (504a) being disposed in the well region (503); wherein the trench gate includes: a silicon oxide filler (202) including a side wall silicon oxide and a bottom silicon oxide; a control gate (402) being located over the trench gate, wherein a side wall of the control gate is enclosed by the side wall silicon oxide, and the control gate (402) is electrically-connected to the planar gate; a

Abstract: An insulated gate bipolar transistor includes a substrate; a first conductivity type base disposed on the substrate and having a first trench; a first conductivity type buffer region disposed in the first conductivity type base; a collector doped region having a second conductivity type and disposed in the first conductivity type base; a second conductivity type base to which the first trench extends downwardly; a gate oxide layer disposed on an inner surface of the first trench; a polysilicon gate disposed inside the gate oxide layer; an emitter doped region having a first conductivity type and disposed in the second conductivity type base and under the first trench; a conductive plug extending downwardly from above the first trench and contacting the second conductivity type base; and an insulating oxide layer filled in the first trench, the insulating oxide layer insulating and isolating the polysilicon gate from the emitter doped region.

Abstract: An integrated circuit chip and a manufacturing method therefor, and a gate drive circuit, the integrated circuit chip comprising: a semiconductor substrate (103), a high voltage island (101a) being formed in the semiconductor substrate (103); a high voltage junction terminal (102a), the high voltage junction terminal (102a) surrounding the high voltage island (101a), a depletion type MOS device (N1) being formed on the high voltage junction terminal (102a), a gate electrode and a drain electrode of the depletion type MOS device (N1) being short connected, and a source electrode of the depletion type MOS device (N1) being connected to a high side power supply end (VB) of the integrated circuit chip; and a bipolar transistor (Q1), a collector electrode of the bipolar transistor (Q1) being short connected to the substrate and being connected to a low side power supply end (VCC) of the integrated circuit chip, an emitter of the bipolar transistor (Q1) being connected to a gate electrode of the depletion type MOS

Abstract: A manufacturing method of an LDMOS device comprises: obtaining a wafer formed with a doped region having a first conductivity type, wherein a top buried layer is formed inside the doped region having the first conductivity type, and a field oxide insulation layer structure is formed on the top buried layer; disposing a trench on the doped region having the first conductivity type, wherein the trench extends to the top buried layer and the field oxide insulation layer structure such that a portion of the top buried layer is removed; injecting an ion of a second conductivity type to form a well region below the trench; and forming a doped source region in the well region. The first conductivity type and the second conductivity type are opposite conductivity types.

Abstract: A lateral double-diffused metal oxide semiconductor component and a manufacturing method therefor. The lateral double-diffused metal oxide semiconductor component comprises: a semiconductor substrate, the semiconductor substrate being provided thereon with a drift area; the drift area being provided therein with a trap area and a drain area, the trap area being provided therein with an active area and a channel; the drift area being provided therein with a deep trench isolation structure arranged between the trap area and the drain area, and the deep trench isolation structure being provided at the bottom thereof with alternately arranged first p-type injection areas and first n-type injection areas.

Abstract: A device integrated with a junction field-effect transistor, the device is divided into a JFET region and a power device area, and the device includes: a drain (201) having a first conduction type; and a first conduction type region (214) disposed on a front face of the drain; the JFET region further includes: a JFET source (208) having a first conduction type; a first well (202) having a second conduction type; a metal electrode (212) formed on the JFET source (208), which is in contact with the JFET source (208); a JFET metal gate (213) disposed on the first well (202) at both sides of the JFET source (208); and a first clamping region (210) located below the JFET metal gate (213) and within the first well (202).

Abstract: A device integrated with JFET, the device is divided into a JFET region and a power device region, and the device includes: a drain (201) with a first conduction type; and a first conduction type region disposed on a front surface of the drain (201); the JFET region includes: a first well (205) with a second conduction type and formed in the first conduction type region; a second well (207) with a second conduction type and formed in the first conduction type region; a JFET source (212) with the first conduction type; a metal electrode formed on the JFET source (212), which is in contact with the JFET source (212); and a second conduction type buried layer (203) formed under the JFET source (212) and the second well (207).

Abstract: A semiconductor device includes a semiconductor substrate, a field oxide layer, a gate plate and field plate integration structure and a plurality of contact holes. A body region and a drift region are formed in the semiconductor substrate. An active region is formed in the body region, and a drain region is formed in the drift region. The field oxide layer is located on the drift region and the drift region surrounds at least part of the field oxide layer. The gate plate and field plate integration structure is provided across the semiconductor substrate and the field oxide layer, and extends onto the body region. The contact hole penetrates into the field oxide layer. The depth of the contact hole near the source region penetrating into the field oxide layer is greater than the depth of the contact hole near the drain region penetrating into the field oxide layer.

Abstract: A VDMOS device and a manufacturing method therefor.

Abstract: A device integrated with a depletion-mode junction field-effect transistor and a method for manufacturing the device. The device includes: a well region, which is of a second conduction type and formed within a first conduction region (214); a JFET source (210), which is of a first conduction type and formed within the well region; a metal electrode (212) of the JFET sources formed on the JFET sources (210), which is in contact with the JFET sources (210); a lateral channel region (208), which is of the first conduction type and formed between two adjacent JFET sources (210), while two ends thereof are in contact with the two adjacent JFET sources (210); and a JFET metal gate (213) formed on the well region.

Abstract: A VDMOS device and a manufacturing method therefor.

Abstract: A method for manufacturing a semiconductor device and an integrated semiconductor device, said method comprising: providing an epitaxial layer having a first region and a second region, forming, in the first region, at least two second doping-type deep wells, and forming, in the second region, at least two second doping-type deep wells; forming a first dielectric island between the second doping-type deep wells and forming a second dielectric island on the second doping-type deep wells; forming a first doping-type trench on two sides of the first dielectric island in the first region; forming a gate structure on the first dielectric island; and forming a separated first doping-type source region by using the second dielectric island as a mask, the first doping-type trench extending, in the first region, transversally to the first doping-type source region.

Abstract: A method for correction of an optical proximity effect, comprising: parsing and dividing the periphery of a design pattern to obtain segments to process; for a segment having a corner comprising a segment side (101) and an adjacent side (102) forming a corner relation with the segment side, setting a target point according to the following principle: when the length of the adjacent side (102) is greater than a preset length, the target point is set at the location of the outer end point (104) of the segment side; when the length of the adjacent side (102) is less than or equal to the preset length, the target point is set between the vertex (103) of the corner and the outer end point (104) of the segment side, and the less the length of the adjacent side (102), the further the target point from the location of the outer end point (104); and adjusting, according to a simulation difference of the target point, the design pattern until it conforms to a design target.

Abstract: A semiconductor device includes a substrate (110); a buried layer (120) formed on the substrate (110), a diffusion layer (130) formed on the buried layer (120), wherein the diffusion layer (130) includes a first diffusion region (132) and a second diffusion region (134), and an impurity type of the second diffusion region (134) is opposite to an impurity type of the first diffusion region (132); the diffusion layer (134) further comprises a plurality of third diffusion regions (136) formed in the second diffusion region, wherein an impurity type of the third diffusion region (136) is opposite to the impurity type of the second diffusion region (134); and a gate (144) formed on the diffusion layer (130).

Abstract: A structure for testing a semiconductor device.

Abstract: A MEMS microphone comprises a substrate (110), a lower electrode layer (120), a sacrificial layer (130), a stress layer (140), and an upper electrode layer (150). The substrate (110) is centrally provided with a first opening (111), and the lower electrode layer (120) stretches across the substrate (110). The sacrificial layer (130), the stress layer (140), and the upper electrode layer (150) are sequentially laminated on the lower electrode layer (120), and a second opening (160) is provided on the sacrificial layer (130) and the stress layer (140). The second opening (160) is provided in correspondence with the first opening (111). A stress direction of the stress layer (140) is reverse to a warpage direction of the substrate (110).

Abstract: A method for improving the conversion efficiency of a CCM mode of a flyback resonant switch power supply, comprising: presetting a threshold value Tset, calculating a time interval Ttap between adjacent zero points during a present conducting time, outputting a switch-off signal at zero points, and comparing the time interval Ttap with the preset threshold value Tset; when Ttap>Tset, he present switch-off time to be less than a switch-off time of a previous cycle, outputting a switch-on signal; when Ttap=0, controlling the present switch-off time to be greater than a switch-off time of the previous cycle, outputting a switch-on signal; and when 0<Ttap<=Tset, controlling the present switch-off time to be the same as the switch-off time of the previous switch cycle, outputting a switch-on signal.