Abstract: A power semiconductor device includes a silicon carbide substrate and has at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The power semiconductor device further includes an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts. Each pit of the pattern of pits has a depth that extends short of the first layer.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device includes a stop layer that is disposed at least in part laterally between the pits. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts, wherein the ohmic metal contacts at least parts of the stop layer.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device includes a stop layer that is disposed at least in part laterally between the pits. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts, wherein the ohmic metal contacts at least parts of the stop layer.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts.

Abstract: A power semiconductor device includes a silicon carbide substrate and at least a first layer or region formed above the substrate. The silicon carbide substrate has a pattern of pits formed thereon. The device further comprising an ohmic metal disposed at least in the pits to form low-resistance ohmic contacts.

Abstract: An insulated gate field effect transistor is disclosed. The transistor includes a semi-insulating silicon carbide substrate, an epitaxial layer of silicon carbide layer adjacent the semi-insulating substrate for providing a drift region having a first conductivity type, and source and drain regions in the epitaxial layer having the same conductivity type as the drift region. A channel region is in the epitaxial layer, has portions between the source and the drain regions, and has the opposite conductivity type from the source and drain regions. The transistor includes contacts to the epitaxial layer for the source, drain and channel regions, an insulating layer over the channel region of the epitaxial layer, and a gate contact adjacent the insulating layer and the channel region.

Abstract: A silicon carbide insulated gate power transistor is disclosed that demonstrates increased maximum voltage. The transistor comprises a field effect or insulated gate transistor with a protective region adjacent the insulated gate that has the opposite conductivity type from the source for protecting the gate insulator material from the degrading or breakdown effects of a large voltage applied across the device.

Abstract: An apparatus and a method for regenerating charge packets representing logical information in a charge transfer device uses a pattern of field plate electrodes and impurity zones to perform arithmetic operations. To regenerate a charge packet it is first multiplied by a factor dependent upon transfer imperfections. Then an amount of charge representing a logical 0 is substracted from the charge packet. Finally, the magnitude of the charge packet is limited to the amount of charge representing a logical 1.