A method of manufacturing a semiconductor device includes: forming, on a surface of an n-type semiconductor layer, an impurity source film containing both aluminum and beryllium; and forming a p-type impurity-doped layer in the n-type semiconductor layer by irradiating the impurity source film with first laser light to simultaneously introduce the aluminum and the beryllium into the n-type semiconductor layer.

A method includes providing a first layer of epitaxial silicon carbide supported by a silicon carbide substrate, providing a second layer of epitaxial silicon carbide on the first layer, forming a plurality of semiconductor devices in the second layer, and separating the substrate from the second layer at the first layer. The first layer includes a plurality of voids.

A method for forming semiconductor devices includes: grinding a backside of a semiconductor wafer with a grinding wheel during a first time interval, wherein the grinding wheel is forward moved during the first time interval, wherein a plurality of semiconductor devices are formed on the semiconductor wafer; polishing the backside of the semiconductor wafer with the grinding wheel in a second time interval, wherein the grinding wheel is backward moved during the second time interval; and dicing the semiconductor wafer to separate the plurality of semiconductor devices from each other without additional polishing of the backside of the semiconductor wafer before dicing the semiconductor wafer.

In a vertical power MOSFET having a superjunction structure, the withstand voltage of the power MOSFET can be ensured even if the aspect ratios of an n-type column region and a p-type column region are increased so as to vary the impurity concentration of the p-type column region. P-type semiconductor regions PR1 are formed on the sides of an n-type column NC1 adjacent to a p-type column region PC1. In this configuration, the p-type semiconductor region PR1 is formed from the upper end of the n-type column region NC1 to about a half depth of a height from the upper end to the lower end of the side of the n-type column region NC1. This inclines the sides of the overall p-type column region including the p-type semiconductor regions PR1 and the p-type column region PC1.

An apparatus for controlling a movement of a grinding wheel of a semiconductor wafer grinding system includes: an interface to obtain a feedback signal including grinding force information indicating a force applied to a semiconductor wafer by the grinding wheel; and a control module to generate a control signal for controlling the movement of the grinding wheel based on the grinding force information. The control module generates the control signal to trigger a forward movement of the grinding wheel according to a desired velocity profile during the grinding, if the grinding force information indicates that a force applied by the grinding wheel is below a force threshold. The control module generates the control signal to trigger a movement of the grinding wheel slower than the desired velocity profile during the grinding, if the grinding force information indicates that the force applied by the grinding wheel is above the force threshold.

A manufacturing method of an anchorage element of a passivation layer, comprising: forming, in a semiconductor body made of SiC and at a distance from a top surface of the semiconductor body, a first implanted region having, along a first axis, a first maximum dimension; forming, in the semiconductor body, a second implanted region, which is superimposed to the first implanted region and has, along the first axis, a second maximum dimension smaller than the first maximum dimension; carrying out a process of thermal oxidation of the first implanted region and second implanted region to form an oxidized region; removing said oxidized region to form a cavity; and forming, on the top surface, the passivation layer protruding into the cavity to form said anchorage element fixing the passivation layer to the semiconductor body.

An integration of silicon carbide (SiC) pressure sensor and a temperature sensor on a single SiC substrate to facilitate the simultaneous measurement of pressure and temperature at temperature, and a method of fabricating the same.

A method of manufacturing a semiconductor device includes: forming, on a surface of an n-type semiconductor layer, an impurity source film containing both aluminum and beryllium; and forming a p-type impurity-doped layer in the n-type semiconductor layer by irradiating the impurity source film with first laser light to simultaneously introduce the aluminum and the beryllium into the n-type semiconductor layer.

In a vertical power MOSFET having a superjunction structure, the withstand voltage of the power MOSFET can be ensured even if the aspect ratios of an n-type column region and a p-type column region are increased so as to vary the impurity concentration of the p-type column region. P-type semiconductor regions PR1 are formed on the sides of an n-type column NC1 adjacent to a p-type column region PC1. In this configuration, the p-type semiconductor region PR1 is formed from the upper end of the n-type column region NC1 to about a half depth of a height from the upper end to the lower end of the side of the n-type column region NC1. This inclines the sides of the overall p-type column region including the p-type semiconductor regions PR1 and the p-type column region PC1.

A SiC composite substrate includes a SiC single crystal layer and at least one biaxially oriented SiC layer. The at least one biaxially oriented SiC layer is disposed on the SiC single crystal. In the biaxially oriented SiC layer, the SiC is oriented in both a c-axis direction and an a-axis direction. The biaxially oriented SiC layer has pores and has a density of defect reaching the surface of 1.0?10.sup.1/cm.sup.2 or less.