Patent application number | Description | Published |
20100301414 | HIGH VOLTAGE NMOS WITH LOW ON RESISTANCE AND ASSOCIATED METHODS OF MAKING - High voltage NMOS devices with low on resistance and associated methods of making are disclosed herein. In one embodiment, a method for making N typed MOSFET devices includes forming an N-well and a P-well with twin well process, forming field oxide, forming gate comprising an oxide layer and a conducting layer, forming a P-base in the P-well, the P-base being self-aligned to the gate, side diffusing the P-base to contact the N-well, and forming N+ source pickup region and N+ drain pickup region. | 12-02-2010 |
20110156199 | LOW LEAKAGE AND/OR LOW TURN-ON VOLTAGE SCHOTTKY DIODE - A Schottky diode and a method of manufacturing the Schottky diode are disclosed. The Schottky diode has an N-well or N-epitaxial layer with a first region, a second region substantially adjacent to an electron doped buried layer that has a donor electron concentration greater than that of the first region, and a third region substantially adjacent to the anode that has a donor electron concentration that is less than that of the first region. The second region may be doped with implanted phosphorus and the third region may be doped with implanted boron. | 06-30-2011 |
20120056294 | SCHOTTKY DIODES WITH DUAL GUARD RING REGIONS AND ASSOCIATED METHODS - The present invention discloses a Schottky diode. The Schottky diode comprises a cathode region, an anode region and a guard ring region. The anode region may comprise a metal Schottky contact. The guard ring region may comprise an outer guard ring and a plurality of inner guard stripes inside the outer guard ring. And wherein the inner guard stripe has a shallower junction depth than the outer guard ring. | 03-08-2012 |
20140015017 | HIGH VOLTAGE SEMICONDUCTOR DEVICE AND THE ASSOCIATED METHOD OF MANUFACTURING - The present disclosure discloses a high voltage semiconductor device and the associated methods of manufacturing. In one embodiment, the high voltage semiconductor device comprises: an epitaxial layer, a first low voltage well formed in the epitaxial layer; a second low voltage well formed in the epitaxial layer; a high voltage well formed in the epitaxial layer, wherein the second low voltage well is surrounded by the high voltage well; a first highly doping region formed in the first low voltage well; a second highly doping region and a third highly doping region formed in the second low voltage well, wherein the third highly doping region is adjacent to the second highly doping region; a field oxide formed in the epitaxial layer as a shallow-trench isolation structure; and a gate region formed on the epitaxial layer. | 01-16-2014 |
20140024186 | METHOD FOR FORMING DUAL GATE INSULATION LAYERS AND SEMICONDUCTOR DEVICE HAVING DUAL GATE INSULATION LAYERS - Method of forming dual gate insulation layers and semiconductor device having dual gate insulation layers is disclosed. The method of forming dual gate insulation layers comprises forming a first thin layer of a thick gate insulation layer on a semiconductor substrate by oxidizing the semiconductor substrate, depositing a second thicker layer of the thick gate insulation layer on the first thin layer, removing a portion of the thick gate insulation layer to expose a surface area of the semiconductor substrate and forming a thin gate insulation layer on the exposed surface area of the semiconductor substrate. The method of forming dual gate insulation layers, when applied in fabricating semiconductor devices having dual gate insulation layers and trench isolation structures, may help to reduce a silicon stress near edges of the trench isolation structures and reduce/alleviate/prevent the formation of a leaky junction around the edges of the trench isolation structures. | 01-23-2014 |
20150084126 | LDMOS DEVICE WITH SHORT CHANNEL AND ASSOCIATED FABRICATION METHOD - A method of fabricating an LDMOS device includes: forming a gate of the LDMOS device on a semiconductor substrate; performing tilt body implantation by implanting dopants of a first conductivity type in the semiconductor substrate using a mask, wherein the tilt body implantation is implanted at an angle from a vertical direction; performing zero tilt body implantation by implanting dopants of the first conductivity type using the same mask, wherein the zero tilt body implantation is implanted with zero tilt from the vertical direction, and wherein the tilt body implantation and the zero tilt body implantation are configured to form a body region of the LDMOS device; and forming a source region and a drain contact region of the LDMOS device, wherein the source region and the drain contact region are of a second conductivity type. | 03-26-2015 |
20150162441 | LDMOS DEVICE WITH IMPROVED AVALANCHE ENERGY AND ASSOCIATED FABRICATING METHOD - A semiconductor device has: a gate region having a dielectric layer and a conducting layer; an N-type drain region having a lightly doped drift region and a highly doped drain contact region formed in the drift region, wherein the drain region is at a first side of the gate region; a P-type body region adjacent to the drain region, the body region having a lightly doped first portion body region, a second portion body region, and a highly doped body contact region; and an N-type highly doped source region in the body region, wherein the source region is at a second side of the gate region; wherein the first portion body region is doped with boron, the second portion body region is doped with boron and indium in the first portion body region, and the second portion body region is located adjacent to and beneath the source region. | 06-11-2015 |
20150187931 | HIGH VOLTAGE PMOS AND THE METHOD FOR FORMING THEREOF - A high voltage PMOS replacing the lightly doped region of the drain region with a low voltage P-well adopted in the low voltage devices, so as to save a mask. In order to achieve the high breakdown voltage and the low on resistance, a thick gate oxide applied in the DMOS is inserted. The N-type well region surrounding the source region may be replaced by a low voltage N-well adopted in the low voltage device to further save a mask. | 07-02-2015 |