Patent application number | Description | Published |
20090039358 | SiC Crystal Semiconductor Device - A method for improving the quality of a SiC layer by effectively reducing or eliminating the carrier trapping centers by high temperature annealing and a SiC semiconductor device fabricated by the method. The method for improving the quality of a SiC layer by eliminating or reducing some carrier trapping centers includes the steps of: (a) carrying out ion implantation of carbon atom interstitials (C), silicon atoms, hydrogen atoms, or helium atoms into a shallow surface layer (A) of the starting SiC crystal layer (E) to introduce excess carbon interstitials into the implanted surface layer, and (b) heating the layer for making the carbon interstitials (C) to diffuse out from the implanted surface layer (A) into a bulk layer (E) and for making the electrically active point defects in the bulk layer inactive. After the above steps, the surface layer (A) can be etched or mechanically removed. The SiC semiconductor device is fabricated by the method. | 02-12-2009 |
20090047772 | Method for Improving the Quality of a SiC Crystal - A method for improving the quality of a SiC layer by effectively reducing or eliminating the carrier trapping centers in the as-grown SiC crystal. The method includes the steps of: (a) carrying out ion implantation of carbon atoms, silicon atoms, hydrogen atoms, or helium atoms into a shallow surface layer of the SiC crystal layer to introduce carbon interstitials into the surface layer, and (b) growing the SiC layer upward from the edge face of the surface layer into which the carbon interstitials have been introduced, and diffusing out the carbon interstitials that have been introduced into the surface layer from the surface layer into the grown layer and combining the carbon interstitials and point defects to make the electrically active point defects in the grown layer inactive. | 02-19-2009 |
20100032686 | Bipolar Semiconductor Device, Method for Producing the Same, and Method for Controlling Zener Voltage - Bipolar semiconductor devices have a Zener voltage controlled very precisely in a wide range of Zener voltages (for example, from 10 to 500 V). A bipolar semiconductor device has a mesa structure and includes a silicon carbide single crystal substrate of a first conductivity type, a silicon carbide conductive layer of a first conductivity type, a highly doped layer of a second conductivity type and a silicon carbide conductive layer of a second conductivity type which substrate and conductive layers are laminated in the order named. | 02-11-2010 |
20100084663 | Silicon Carbide Zener Diode - A silicon carbide Zener diode is a bipolar semiconductor device that has a mesa structure and includes a silicon carbide single crystal substrate of a first conductivity type, formed thereon, a silicon carbide conductive layer of a first conductivity type, and a silicon carbide conductive layer of a second conductivity type formed on the silicon carbide conductive layer of a first conductivity type, wherein a depletion layer that is formed under reverse bias at a junction between the silicon carbide conductive layer of a first conductivity type and the silicon carbide conductive layer of a second conductivity type does not reach a mesa corner formed in the silicon carbide conductive layer of a first conductivity type. | 04-08-2010 |
20100173475 | Method for Improving the Quality of a SiC Crystal - A method for improving the quality of a SiC layer by effectively reducing or eliminating the carrier trapping centers in the as-grown SiC crystal. The method includes the steps of: (a) carrying out ion implantation of carbon atoms, silicon atoms, hydrogen atoms, or helium atoms into a shallow surface layer of the SiC crystal layer to introduce carbon interstitials into the surface layer, and (b) growing the SiC layer upward from the edge face of the surface layer into which the carbon interstitials have been introduced, and diffusing out the carbon interstitials that have been introduced into the surface layer from the surface layer into the grown layer and combining the carbon interstitials and point defects to make the electrically active point defects in the grown layer inactive. | 07-08-2010 |
20100258816 | Silicon carbide semiconductor device and manufacturing method therefor - With a view to preventing increases in forward voltage due to a change with the lapse of time of a bipolar semiconductor device using a silicon carbide semiconductor, a buffer layer, a drift layer and other p-type and n-type semiconductor layers are formed on a growth surface, which is given by a surface of a crystal of a silicon carbide semiconductor having an off-angle θ of 8 degrees from a (000-1) carbon surface of the crystal, at a film growth rate having a film-thickness increasing rate per hour h of 10 μm/h, which is three times or more higher than conventional counterparts. The flow rate of silane and propane material gases and dopant gases is largely increased to enhance the film growth rate. | 10-14-2010 |
20100258817 | Silicon carbide semiconductor device and manufacturing method therefor - With a view to preventing increases in forward voltage due to a change with the lapse of time of a bipolar semiconductor device using a silicon carbide semiconductor, a buffer layer, a drift layer and other p-type and n-type semiconductor layers are formed on a growth surface, which is given by a surface of a crystal of a silicon carbide semiconductor having an off-angle θ of 8 degrees from a (000-1) carbon surface of the crystal, at a film growth rate having a film-thickness increasing rate per hour h of 10 μm/h, which is three times or more higher than conventional counterparts. The flow rate of silane and propane material gases and dopant gases is largely increased to enhance the film growth rate. | 10-14-2010 |
20100261333 | Silicon carbide semiconductor device and manufacturing method therefor - With a view to preventing increases in forward voltage due to a change with the lapse of time of a bipolar semiconductor device using a silicon carbide semiconductor, a buffer layer, a drift layer and other p-type and n-type semiconductor layers are formed on a growth surface, which is given by a surface of a crystal of a silicon carbide semiconductor having an off-angle θ of 8 degrees from a (000-1) carbon surface of the crystal, at a film growth rate having a film-thickness increasing rate per hour h of 10 μm/h, which is three times or more higher than conventional counterparts. The flow rate of silane and propane material gases and dopant gases is largely increased to enhance the film growth rate. | 10-14-2010 |
20110006309 | EPITAXIAL SiC SINGLE CRYSTAL SUBSTRATE AND METHOD OF MANUFACTURE OF EXPITAXIAL SiC SINGLE CRYSTAL SUBSTRATE - An epitaxial SiC single crystal substrate including a SiC single crystal wafer whose main surface is a c-plane or a surface that inclines a c-plane with an angle of inclination that is more than 0 degree but less than 10 degrees, and SiC epitaxial film that is formed on the main surface of the SiC single crystal wafer, wherein the dislocation array density of threading edge dislocation arrays that are formed in the SiC epitaxial film is 10 arrays/cm | 01-13-2011 |
20130009170 | EPITAXIAL SiC SINGLE CRYSTAL SUBSTRATE AND METHOD OF MANUFACTURE OF EPITAXIAL SiC SINGLE CRYSTAL SUBSTRATE - An epitaxial SiC single crystal substrate including a SiC single crystal wafer whose main surface is a c-plane or a surface that inclines a c-plane with an angle of inclination that is more than 0 degree but less than 10 degrees, and SiC epitaxial film that is formed on the main surface of the SiC single crystal wafer, wherein the dislocation array density of threading edge dislocation arrays that are formed in the SiC epitaxial film is 10 arrays/cm | 01-10-2013 |
20130152853 | FILM-FORMING APPARATUS AND FILM-FORMING METHOD - A film-forming apparatus | 06-20-2013 |
20140287539 | FILM FORMATION APPARATUS AND FILM FORMATION METHOD - At the time of transporting a substrate into or from a space where a film formation process is performed, the space where the film formation process is performed, a space where a lower heater | 09-25-2014 |