Methods of maintaining a state of a memory cell without interrupting access to the memory cell are provided, including applying a back bias to the cell to offset charge leakage out of a floating body of the cell, wherein a charge level of the floating body indicates a state of the memory cell; and accessing the cell.

A semiconductor device includes first, second, third, and fourth electrodes, a first insulating film, and first, second third, and fourth silicon carbide layers. A first distance between the first electrode and a first interface between the fourth electrode and fourth silicon carbide region is longer than a second distance between the first insulating film and a second interface between the third silicon carbide region and the fourth silicon carbide region. The fourth silicon carbide region is between the third silicon carbide region and the second silicon carbide region in a direction perendicular to the second interface.

A power semiconductor device is comprised of a plurality of zones having similar structure. Each of the zones may be characterized by a switching loss during transitions to a non-conducting state. The device is configured such that the switching loss is different between at least two of the zones. Further, the device is configured such that zones having greater switching losses transition to the non-conducting state before zones having lesser switching losses.

A method of manufacturing a super junction MOSFET, which includes a parallel pn layer including a plurality of pn junctions and in which an n-type drift region and a p-type partition region interposed between the pn junctions are alternately arranged and contact each other, a MOS gate structure on the surface of the parallel pn layer, and an n-type buffer layer in contact with an opposite main surface. The impurity concentration of the buffer layer is equal to or less than that of the n-type drift region. At least one of the p-type partition regions in the parallel pn layer is replaced with an n region with a lower impurity concentration than the n-type drift region.

A semiconductor device according to an embodiment includes a SiC layer having a first plane and a second plane, a gate insulating film provided on the first plane, a gate electrode provided on the gate insulating film, a first SiC region of a first conductivity type provided in the SiC layer, a second SiC region of a second conductivity type provided in the first SiC region, a third SiC region of the first conductivity type provided in the second SiC region, and a fourth SiC region of the first conductivity type provided between the second SiC region and the gate insulating film, the fourth SiC region interposed between the second SiC regions, and the fourth SiC region provided between the first SiC region and the third SiC region.

A method of manufacturing a semiconductor device includes: forming a lattice defect layer in a substrate having a front surface region where a bipolar element of a pn junction type is formed and a rear surface region opposing the front surface region, the lattice defect layer being formed by injecting a charged particle to a first region in the rear surface region of the substrate; forming a laminated region, in which a first conductivity type impurity region and a second conductivity type impurity region are sequentially laminated from a rear surface side of the substrate toward the first region, in a second region in the rear surface region of the substrate, the first region being positioned deeper than the second region from a rear surface of the substrate; and selectively activating the laminated region by laser annealing after the formation of the laminated region and the lattice defect layer.

This invention discloses a semiconductor device disposed in a semiconductor substrate. The semiconductor device includes a first semiconductor layer of a first conductivity type on a first major surface. The semiconductor device further includes a second semiconductor layer of a second conductivity type on a second major surface opposite the first major surface. The semiconductor device further includes an injection efficiency controlling buffer layer of a first conductivity type disposed immediately below the second semiconductor layer to control the injection efficiency of the second semiconductor layer.

A method for forming a power semiconductor device is provided. The method includes providing a substrate having a first surface and a second surface; and forming a plurality of trenches in the second surface of the substrate. The method also includes forming a semiconductor pillar in each of the plurality of trenches, wherein the semiconductor pillars and the substrate form a plurality of super junctions of the power semiconductor device for increasing the breakdown voltage of the power semiconductor device and reducing the on-stage voltage of the power semiconductor device; and forming a gate structure on the first surface of the substrate. Further, the method includes forming a plurality of well regions in the first surface of the substrate around the gate structure; and forming a source region in each of the plurality of well regions around the gate structure.

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.

An IGBT includes a floating P well, and a floating N+ well that extends down into the floating P well. A bottom surface of the floating P well has a waved contour so that it has thinner portions and thicker portions. When the device is on, electrons flow laterally from an N+ emitter, and through a first channel region. Some electrons pass downward, but others pass laterally through the floating N+ well to a local bipolar transistor located at a thinner portion of the floating P type well. The transistor injects electrons down into the N drift layer. Other electrons pass farther through the floating N+ well, through the second channel region, and to an electron injector portion of the N drift layer. The extra electron injection afforded by the floating well structures reduces V.sub.CE(SAT). The waved contour is made without adding any masking step to the IGBT manufacturing process.