Patent application number | Description | Published |
20090014790 | SEMICONDUCTOR DEVICE AND METHOD OF FABRICATING SEMICONDUCTOR DEVICE - A semiconductor device includes a gate electrode formed through an insulating film in a groove having a first side surface adjacent to a source region and a base region, and a second conductive type first impurity region formed adjacent to a second side surface of the groove between the groove and a lead-out portion of a drain region existing below the base region so as to extend downward beyond a lower end of the groove. | 01-15-2009 |
20090197378 | METHOD OF FABRICATING SEMICONDUCTOR DEVICE - A method of fabricating a semiconductor device includes a first step of forming a defect suppression film suppressing increase in a defect due to implantation of an impurity on a semiconductor substrate, a second step of forming an active region on a surface of the semiconductor substrate by implanting the impurity through the defect suppression film, a third step of removing the defect suppression film and a fourth step of forming an interface state suppression film suppressing increase in an interface state density of the active region on the active region. | 08-06-2009 |
20090261410 | DMOS TRANSISTOR - This invention provides a DMOS transistor that has a reduced ON resistance and is prevented from deterioration in strength against an electrostatic discharge. An edge portion of a source layer of the DMOS transistor is disposed so as to recede from an inner corner portion of a gate electrode. A silicide layer is structured so as not to extend out of the edge portion of the source layer. That is, although the silicide layer is formed on a surface of the source layer, the silicide layer is not formed on a surface of a portion of a body layer, which is exposed between the source layer and the inner corner portion of the gate electrode. As a result, the strength against the electrostatic discharge can be improved, because an electric current flows almost uniformly through whole of the DMOS transistor without converging. | 10-22-2009 |
20090278200 | TRANSISTOR, SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - An ON resistance of a trench gate type transistor and a withstand voltage of a planar type transistor are optimized at the same time. Each of first and second regions of a semiconductor layer is formed by epitaxial growth on each of first and second regions of a semiconductor substrate, respectively. A first buried layer is formed between the first region of the semiconductor substrate and the first region of the semiconductor layer, while a second buried layer is formed between the second region of the semiconductor substrate and the second region of the semiconductor layer. The first buried layer is formed of an N | 11-12-2009 |
20100187653 | SEMICONDUCTOR DEVICE - A conventional semiconductor device has a problem that an on-current of a parasitic transistor flows through a surface portion of a semiconductor layer and thus a semiconductor element undergoes thermal breakdown. In a semiconductor device according to the present invention, a protection element is formed with use of an isolation region and N type buried layers. A PN junction region in the protection element is formed on a P type buried layer of the isolation region. The PN junction region has a junction breakdown voltage lower than that of a PN junction region of a semiconductor element to be protected. This structure allows an on-current of a parasitic transistor to flow into the protection element, and thereby the semiconductor element is protected. In addition, the on-current of the parasitic transistor flows through a deep portion of the epitaxial layer, and thereby the protection element is prevented from thermal breakdown. | 07-29-2010 |
20100207197 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - In the semiconductor device according to the present invention, a P type diffusion layer and an N type diffusion layer as a drain lead region are formed on an N type diffusion layer as a drain region. The P type diffusion layer is disposed between a source region and the drain region of the MOS transistor. When a positive ESD surge is applied to a drain electrode, causing an on-current of a parasite transistor to flow, this structure allows the on-current of the parasite transistor to take a path flowing through a deep portion of an epitaxial layer. Thus, the heat breakdown of the MOS transistor is prevented. | 08-19-2010 |
20110204952 | CURRENT DETECTION CIRCUIT AND SEMICONDUCTOR INTEGRATED CIRCUIT - The invention provides a current detection circuit for a transistor, that does not influence a current flowing through the transistor, and minimizes a power loss, an increase of the pattern area and so on. A current detection circuit includes a wiring connected to a MOS transistor and forming a current path of a current of the MOS transistor, a current detection MOS transistor of which the gate is connected to the wiring, that flows a current corresponding to the potential of the gate, and a current detector detecting a current flowing through the current detection MOS transistor. The current detection circuit is configured including a load resistor connected to the current detection MOS transistor and a voltage detection circuit detecting a drain voltage of the current detection MOS transistor. | 08-25-2011 |
20120112240 | SEMICONDUCTOR DEVICE - An N type layer made of an N type epitaxial layer in which an N+ type drain layer etc are formed is surrounded by a P type drain isolation layer extending from the front surface of the N type epitaxial layer to an N+ type buried layer. A P type collector layer is formed in an N type layer made of the N type epitaxial layer surrounded by the P type drain isolation layer and a P type element isolation layer, extending from the front surface to the inside of the N type layer. A parasitic bipolar transistor that uses the first conductive type drain isolation layer as the emitter, the second conductive type N type layer as the base, and the collector layer as the collector is thus formed so as to flow a surge current into a ground line. | 05-10-2012 |
20120299114 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - The invention is directed to a semiconductor device which is manufactured by a BiCMOS process in which a process of manufacturing a V-NPN transistor is rationalized. Furthermore, the hFE of the transistor is adjusted to a large value. An N type base width control layer is formed being in contact with a bottom portion of a P type base region under an N+ type emitter region. The N type base width control layer shallows a portion of the P type base region under the N+ type emitter region partially. The P type base region is formed by using a process of forming a P type well region, and the N type base width control layer is formed by using a process of forming an N type well region, thereby achieving the process rationalization. | 11-29-2012 |
20130075864 | SEMICONDUCTOR DEVICE - An ESD protection element is formed by a PN junction diode including an N+ type buried layer having a proper impurity concentration and a P+ type buried layer and a parasitic PNP bipolar transistor which uses a P+ type drawing layer connected to a P+ type diffusion layer as the emitter, an N− type epitaxial layer as the base, and a P type semiconductor substrate as the collector. The P+ type buried layer is connected to an anode electrode, and the P+ type diffusion layer and an N+ type diffusion layer connected to and surrounding the P+ type diffusion layer are connected to a cathode electrode. When a large positive static electricity is applied to the cathode electrode, the parasitic PNP bipolar transistor turns on to flow a large discharge current. | 03-28-2013 |
20130075865 | SEMICONDUCTOR DEVICE - An ESD protection element is formed by a PN junction diode including an N+ type buried layer having a proper impurity concentration and a first P+ type buried layer and a parasitic PNP bipolar transistor which uses a second P+ type buried layer connected to a P+ type diffusion layer as the emitter, an N− type epitaxial layer as the base, and the first P+ type buried layer as the collector. The first P+ type buried layer is connected to an anode electrode, and the P+ type diffusion layer and an N+ type diffusion layer surrounding the P+ type diffusion layer are connected to a cathode electrode. When a large positive static electricity is applied to the cathode electrode, and the parasitic PNP bipolar transistor turns on to flow a large discharge current. | 03-28-2013 |
20130075866 | SEMICONDUCTOR DEVICE - A PN junction diode is formed by an N+ type buried layer having a proper impurity concentration and a P+ type buried layer. The P+ type buried layer is combined with a P+ type drawing layer to penetrate an N− type epitaxial layer and be connected to an anode electrode. An N+ type diffusion layer and a P+ type diffusion layer connected to and surrounding the N+ type diffusion layer are formed in the N− type epitaxial layer surrounded by the P+ type buried layer etc. The N+ type diffusion layer and the P+ type diffusion layer are connected to a cathode electrode. An ESD protection element is formed by the PN junction diode and a parasitic PNP bipolar transistor which uses the P+ type diffusion layer as the emitter, the N− type epitaxial layer as the base, and the P+ type drawing layer etc as the collector. | 03-28-2013 |
20140247527 | CIRCUIT INCLUDING A RESISTIVE ELEMENT, A DIODE, AND A SWITCH AND A METHOD OF USING THE SAME - An ESD protection element can have a high ESD protection characteristic which has a desired breakdown voltage and flows a large discharge current. A junction diode is formed by an N+ type buried layer having a proper impurity concentration and a P+ type buried layer. The P+ type buried layer is combined with a P+ type drawing layer to penetrate an N− type epitaxial layer and be connected to an anode element. An N+ type diffusion layer and a P+ typed diffusion layer connected to an surrounding the N+ type diffusion layer are formed in the N− epitaxial layer surrounded by the P+ type buried layer etc. The N+ type diffusion layer and P+ type diffusion layer are connected to a cathode electrode. An ESD protection element is formed by the PN junction diode and a parasitic PNP bipolar transistor which uses the P+ type diffusion layer as an emitted, the N− type epitaxial layer as the base, and the P+ type drawing layer etc. as the collector. | 09-04-2014 |