Patent application number | Description | Published |
20080224204 | PROCESS FOR MANUFACTURING A MULTI-DRAIN ELECTRONIC POWER DEVICE INTEGRATED IN SEMICONDUCTOR SUBSTRATE AND CORRESPONDING DEVICE - A process manufactures a multi-drain power electronic device integrated on a semiconductor substrate of a first type of conductivity whereon a drain semiconductor layer is formed. The process includes: forming a first semiconductor epitaxial layer of the first type of conductivity of a first value of resistivity forming the drain epitaxial layer on the semiconductor substrate, forming first sub-regions of a second type of conductivity by means of a first selective implant step with a first implant dose, forming second sub-regions of the first type of conductivity by means of a second implant step with a second implant dose, forming a surface semiconductor layer wherein body regions of the second type of conductivity are formed being aligned with the first sub-regions, carrying out a thermal diffusion process so that the first sub-regions form a single electrically continuous column region being aligned and in electric contact with the body regions. | 09-18-2008 |
20090001460 | PROCESS FOR MANUFACTURING A MULTI-DRAIN ELECTRONIC POWER DEVICE INTEGRATED IN SEMICONDUCTOR SUBSTRATE AND CORRESPONDING DEVICE - A process manufactures a multi-drain power electronic device on a semiconductor substrate of a first conductivity type and includes: forming a first semiconductor layer of the first conductivity type on the substrate, forming a second semiconductor layer of a second conductivity type on the first semiconductor layer, forming, in the second semiconductor layer, a first plurality of implanted regions of the first conductivity type using a first implant dose, forming, above the second semiconductor layer, a superficial semiconductor layer of the first conductivity type, forming in the surface semiconductor layer body regions of the second conductivity type, thermally diffusing the implanted regions to form a plurality of electrically continuous implanted column regions along the second semiconductor layer, the plurality of implanted column regions delimiting a plurality of column regions of the second conductivity type aligned with the body regions. | 01-01-2009 |
20090159969 | PROCESS FOR MANUFACTURING A SEMICONDUCTOR POWER DEVICE COMPRISING CHARGE-BALANCE COLUMN STRUCTURES AND RESPECTIVE DEVICE - Process for manufacturing a semiconductor power device, wherein a trench is formed in a semiconductor body having a first conductivity type; the trench is annealed for shaping purpose; and the trench is filled with semiconductor material via epitaxial growth so as to obtain a first column having a second conductivity type. The epitaxial growth is performed by supplying a gas containing silicon and a gas containing dopant ions of the second conductivity type in presence of a halogenide gas and occurs with uniform distribution of the dopant ions. The flow of the gas containing dopant ions is varied according to a linear ramp during the epitaxial growth; in particular, in the case of selective growth of the semiconductor material in the presence of a hard mask, the flow decreases; in the case of non-selective growth, in the absence of hard mask, the flow increases. | 06-25-2009 |
20110034010 | PROCESS FOR MANUFACTURING A MULTI-DRAIN ELECTRONIC POWER DEVICE INTEGRATED IN SEMICONDUCTOR SUBSTRATE AND CORRESPONDING DEVICE - A process manufactures a multi-drain power electronic device on a semiconductor substrate of a first conductivity type and includes: forming a first semiconductor layer of the first conductivity type on the substrate, forming a second semiconductor layer of a second conductivity type on the first semiconductor layer, forming, in the second semiconductor layer, a first plurality of implanted regions of the first conductivity type using a first implant dose, forming, above the second semiconductor layer, a superficial semiconductor layer of the first conductivity type, forming in the surface semiconductor layer body regions of the second conductivity type, thermally diffusing the implanted regions to form a plurality of electrically continuous implanted column regions along the second semiconductor layer, the plurality of implanted column regions delimiting a plurality of column regions of the second conductivity type aligned with the body regions. | 02-10-2011 |
20110079794 | METHOD FOR MANUFACTURING ELECTRONIC DEVICES INTEGRATED IN A SEMICONDUCTOR SUBSTRATE AND CORRESPONDING DEVICES - A method manufactures a vertical power MOS transistor on a semiconductor substrate comprising a first superficial semiconductor layer of a first conductivity type, comprising: forming trench regions in the first semiconductor layer, filling in said trench regions with a second semiconductor layer of a second conductivity type, to form semiconductor portions of the second conductivity type contained in the first semiconductor layer, carrying out an ion implantation of a first dopant type in the semiconductor portions for forming respective implanted body regions of said second conductivity type, carrying out an ion implantation of a second dopant type in one of the implanted body regions for forming an implanted source region of the first conductivity type inside one of the body regions, carrying out an activation thermal process of the first and second dopant types with low thermal budget suitable to complete said formation of the body and source regions. | 04-07-2011 |
20120187479 | PROCESS FOR MANUFACTURING A POWER SEMICONDUCTOR DEVICE HAVING CHARGE-BALANCE COLUMNAR STRUCTURES ON A NON-PLANAR SURFACE, AND CORRESPONDING POWER SEMICONDUCTOR DEVICE - An embodiment of a process for manufacturing a power semiconductor device envisages the steps of: providing a body of semiconductor material having a top surface and having a first conductivity; forming columnar regions having a second type of conductivity within the body of semiconductor material, and surface extensions of the columnar regions above the top surface; and forming doped regions having the second type of conductivity, in the proximity of the top surface and in contact with the columnar regions. The doped regions are formed at least partially within the surface extensions of the columnar regions; the surface extensions and the doped regions have a non-planar surface pattern, in particular with a substantially V-shaped groove. | 07-26-2012 |
20120187480 | PROCESS FOR MANUFACTURING A POWER SEMICONDUCTOR DEVICE HAVING CHARGE-BALANCE COLUMNAR STRUCTURES ON A NON-PLANAR SURFACE, AND CORRESPONDING POWER SEMICONDUCTOR DEVICE - An embodiment of a process for manufacturing a power semiconductor device envisages the steps of: providing a body of semiconductor material having a top surface and having a first conductivity; forming columnar regions having a second type of conductivity within the body of semiconductor material, and surface extensions of the columnar regions above the top surface; and forming doped regions having the second type of conductivity, in the proximity of the top surface and in contact with the columnar regions. The doped regions are formed at least partially within the surface extensions of the columnar regions; the surface extensions and the doped regions have a non-planar surface pattern, in particular with a substantially V-shaped groove. | 07-26-2012 |
20120319191 | PROCESS FOR MANUFACTURING A SEMICONDUCTOR POWER DEVICE COMPRISING CHARGE-BALANCE COLUMN STRUCTURES AND RESPECTIVE DEVICE - Process for manufacturing a semiconductor power device, wherein a trench is formed in a semiconductor body having a first conductivity type; the trench is annealed for shaping purpose; and the trench is filled with semiconductor material via epitaxial growth so as to obtain a first column having a second conductivity type. The epitaxial growth is performed by supplying a gas containing silicon and a gas containing dopant ions of the second conductivity type in presence of a halogenide gas and occurs with uniform distribution of the dopant ions. The flow of the gas containing dopant ions is varied according to a linear ramp during the epitaxial growth; in particular, in the case of selective growth of the semiconductor material in the presence of a hard mask, the flow decreases; in the case of non-selective growth, in the absence of hard mask, the flow increases. | 12-20-2012 |