A method for separating dies from a semiconductor substrate having dies adjoining a first surface of the substrate includes: attaching the substrate to a carrier via the first surface; generating first modifications by introducing laser irradiation into an interior of the substrate via a second surface of the substrate, the first modifications extending between the first surface and a vertical level in the interior that is being spaced from the second surface, the first modifications laterally surrounding the dies; generating second modifications by introducing laser irradiation into the interior via the second surface, the second modifications sub-dividing the substrate into a first part between the first surface and the second modifications, and a second part between the second surface and the second modifications; separating the parts along a first separation area defined by the second modifications; and separating the dies along a second separation area defined by the first modifications.

A silicon carbide semiconductor power transistor and a method of manufacturing the same. The silicon carbide semiconductor power transistor of the disclosure includes a substrate made of silicon carbide (SiC), a drift layer disposed on the substrate, a gate layer formed on the drift layer, a plurality of first and second well pick-up regions disposed in the drift layer, a plurality of source electrodes, and a plurality of contacts. A plurality of V-grooves is formed in the drift layer. A first opening is formed in the gate layer at a bottom of each of the V-grooves, and a second opening is formed in the gate layer at a top of the drift layer between the V-grooves. The plurality of contacts is disposed inside the second opening to be in direct contact with the second well pick-up regions.

A method for forming a hybrid semiconductor device includes growing a stack of layers on a semiconductor substrate. The stack of layers includes a bottom layer in contact with the substrate, a middle layer on the bottom layer and a top layer on the middle layer. First and second transistors are formed on the top layer. A protective dielectric is deposited over the first and second transistors. A trench is formed adjacent to the first transistors to expose the middle layer. The middle layer is removed from below the first transistors to form a cavity. A dielectric material is deposited in the cavity to provide a transistor on insulator structure for the first transistors and a bulk substrate structure for the second transistors.

Devices and methods for forming a device are presented. The method for forming the device includes providing a support substrate having first crystal orientation. A trap rich layer is formed on the support substrate. An insulator layer is formed over a top surface of the trap rich layer. The method further includes forming a top surface layer having second crystal orientation on the insulator layer. The support substrate, the trap rich layer, the insulator layer and the top surface layer correspond to a substrate and the substrate is defined with at least first and second device regions. A transistor is formed in the top surface layer in the first device region and a wide band gap device is formed in the second device region.

A method of manufacturing a semiconductor device that includes a junction field effect transistor, the junction field effect transistor including a semiconductor substrate of a first conductivity type, an epitaxial layer of the first conductivity type formed on the semiconductor substrate, a source region of the first conductivity type formed on a surface of the epitaxial layer, a channel region of the first conductivity type formed in a lower layer of the source region, a pair of trenches formed in the epitaxial layer so as to sandwich the source region therebetween, and a pair of gate regions of a second conductivity type, opposite to the first conductivity type, formed below a bottom of the pair of trenches.

In a silicon carbide semiconductor device, a trench penetrates a source region and a first gate region and reaches a drift layer. On an inner wall of the trench, a channel layer of a first conductivity-type is formed by epitaxial growth. On the channel layer, a second gate region of a second conductivity-type is formed. A first depressed portion is formed at an end portion of the trench to a position deeper than a thickness of the source region so as to remove the source region at the end portion of the trench. A corner portion of the first depressed portion is covered by a second conductivity-type layer.

A semiconductor device includes a first drain region that is made primarily of SiC, a drift layer, a channel region, a first source region, a source electrode that is formed on the first source region, a second drain region that is connected to the first source region, a second source region that is formed separated from the second drain region, a first floating electrode that is connected to the second source region and to the channel region, first gate electrodes, and a second gate electrode that is connected to the first gate electrodes.

An SiC semiconductor device has a p type region including a low concentration region and a high concentration region filled in a trench formed in a cell region. A p type column is provided by the low concentration region, and a p.sup.+ type deep layer is provided by the high concentration region. Thus, since a SJ structure can be made by the p type column and the n type column provided by the n type drift layer, an on-state resistance can be reduced. As a drain potential can be blocked by the p.sup.+ type deep layer, at turnoff, an electric field applied to the gate insulation film can be alleviated and thus breakage of the gate insulation film can be restricted. Therefore, the SiC semiconductor device can realize the reduction of the on-state resistance and the restriction of breakage of the gate insulation film.

A method for fabricating field effect transistors using carbon doped silicon layers to substantially reduce the diffusion of a doped screen layer formed below a substantially undoped channel layer includes forming an in-situ epitaxial carbon doped silicon substrate that is doped to form the screen layer in the carbon doped silicon substrate and forming the substantially undoped silicon layer above the carbon doped silicon substrate. The method may include implanting carbon below the screen layer and forming a thin layer of in-situ epitaxial carbon doped silicon above the screen layer. The screen layer may be formed either in a silicon substrate layer or the carbon doped silicon substrate.

A semiconductor device of an embodiment includes a SiC layer having a surface inclined with respect to a {000-1} face at an angle of 0 to 10 or a surface a normal line direction of which is inclined with respect to a <000-1> direction at an angle of 80 to 90, a gate electrode, an insulating layer at least a part of which is provided between the surface and the gate electrode, and a region, at least apart of which is provided between the surface and the insulating layer, including a bond between carbon and carbon.