Abstract: It is an object to provide technology enabling reduction in variation of an oxygen concentration among silicon wafers. A semiconductor device manufacturing method includes: a first step of introducing oxygen to increase an oxygen concentration of a silicon wafer when the oxygen concentration of the silicon wafer is lower than a predetermined threshold, and deriving oxygen to decrease the oxygen concentration of the silicon wafer when the oxygen concentration of the silicon wafer is higher than the threshold; a second step of forming a first surface structure; a third step of grinding the silicon wafer from a second surface; and a fourth step of forming a second surface structure.

Abstract: A silicon carbide layer has an active region and an outer peripheral region arranged along an outer periphery of the active region in an in-plane direction. First well regions are arranged in the active region. A second well region is arranged in the outer peripheral region. Ohmic electrodes are arranged on a second surface of the silicon carbide layer, are connected to a source electrode, are electrically and ohmically connected to the first well regions, and have surface regions ohmically contacting a part forming the second surface of the silicon carbide layer and having a second conductivity type. The active region includes a standard region part and a thinned region part between the standard region part and the outer peripheral region. The surface regions are arranged at surface density lower in the thinned region part than in the standard region part in a plan view.

Abstract: Fluctuations in device characteristics are suppressed by suppressing local occurrences of a large current through a body diode of a field-effect transistor. A silicon carbide semiconductor device includes a silicon carbide semiconductor substrate, a semiconductor layer formed on the upper surface of the silicon carbide semiconductor substrate, and a backside electrode formed on the lower surface of the silicon carbide semiconductor substrate. A region in which electric resistivity takes a first value is regarded as a first resistance region, and a region where the electric resistivity takes a second value greater than the first value is regarded as a second resistance region. The second resistance region extends across a region boundary, i.e., the boundary between the active region and the termination region, in plan view.

Abstract: The present disclosure has an object of providing a silicon carbide semiconductor device with high productivity which prevents characteristic degradation occurring when a large current is applied to a body diode. A structure including a SiC substrate, a buffer layer, and a drift layer is classified into an active region through which a current flows with application of a voltage to the SiC-MOSFET, and a breakdown voltage support region around a periphery of the active region in a plan view. The active region is classified into a first active region in a center portion, and a second active region between the first active region and the breakdown voltage support region in the plan view. Lifetimes of minority carriers in the second active region and the breakdown voltage support region are shorter than that in the first active region.

Abstract: A superjunction layer includes first pillars of a first conductivity type and second pillars of a second conductivity type. First wells are provided respectively on the second pillars to reach the first pillars and are of the second conductivity type. First impurity regions are provided respectively on the first wells and are of the first conductivity type. Second wells are provided respectively on the first pillars, spaced from the second pillars in a section of an active region that is perpendicular to a semiconductor layer, and are of the second conductivity type. Second impurity regions are provided respectively on the second wells and are of the first conductivity type.

Abstract: A superjunction layer includes first pillars of a first conductivity type and second pillars of a second conductivity type. First wells are provided respectively on the second pillars to reach the first pillars and are of the second conductivity type. First impurity regions are provided respectively on the first wells and are of the first conductivity type. Second wells are provided respectively on the first pillars, spaced from the second pillars in a section of an active region that is perpendicular to a semiconductor layer, and are of the second conductivity type. Second impurity regions are provided respectively on the second wells and are of the first conductivity type.

Abstract: A method for manufacturing a SiC epitaxial wafer includes: a first step of, by supplying a Si supply gas and a C supply gas, performing a first epitaxial growth on a SiC bulk substrate with a 4H—SiC(0001) having an off-angle of less than 5° as a main surface at a first temperature of 1480° C. or higher and 1530° C. or lower; a second step of stopping the supply of the Si supply gas and the C supply gas and increasing a temperature of the SiC bulk substrate from the first temperature to a second temperature; and a third step of, by supplying the Si supply gas and the C supply gas, performing a second epitaxial growth on the SiC bulk substrate having the temperature increased in the second step at the second temperature.

Abstract: A silicon carbide semiconductor device capable of achieving a decrease in ON resistance and an increase in breakdown voltage and a method for manufacturing a silicon carbide semiconductor device. A silicon carbide semiconductor device includes a silicon carbide substrate and a drift layer. The drift layer includes a breakdown voltage holding layer extending from a point where a doping concentration has a predetermined value to a surface of the drift layer. The doping concentration in the breakdown voltage holding layer continuously decreases from the point where the doping concentration has the predetermined value to a modulation point located further toward the surface of the drift layer than a midpoint in a film thickness direction of the breakdown voltage holding layer. The doping concentration in the breakdown voltage holding layer continuously increases from the modulation point to the surface of the drift layer.

Abstract: A silicon carbide semiconductor device capable of achieving a decrease in ON resistance and an increase in breakdown voltage and a method for manufacturing a silicon carbide semiconductor device. A silicon carbide semiconductor device includes a silicon carbide substrate and a drift layer. The drift layer includes a breakdown voltage holding layer extending from a point where a doping concentration has a predetermined value to a surface of the drift layer. The doping concentration in the breakdown voltage holding layer continuously decreases from the point where the doping concentration has the predetermined value to a modulation point located further toward the surface of the drift layer than a midpoint in a film thickness direction of the breakdown voltage holding layer. The doping concentration in the breakdown voltage holding layer continuously increases from the modulation point to the surface of the drift layer.

Abstract: A method for manufacturing a SiC epitaxial wafer includes: a first step of, by supplying a Si supply gas and a C supply gas, performing a first epitaxial growth on a SiC bulk substrate with a 4H—SiC(0001) having an off-angle of less than 5° as a main surface at a first temperature of 1480° C. or higher and 1530° C. or lower; a second step of stopping the supply of the Si supply gas and the C supply gas and increasing a temperature of the SiC bulk substrate from the first temperature to a second temperature; and a third step of, by supplying the Si supply gas and the C supply gas, performing a second epitaxial growth on the SiC bulk substrate having the temperature increased in the second step at the second temperature.