Process flow for a stacked power diode and design of the resulting diode is disclosed. Blanket epitaxy over heavy doped wafers is performed. By controlling dopant addition during epitaxy, desired n-type, diode base, and p-type doping profiles and thicknesses achieved. V-groove pattern if formed on wafers by depositing mask film, lithography and anisotropic etch. Islands surrounded by V-grooves define individual diodes. V-grooves serve as side insulation. Next, oxidation step passivates V-grooves. Further, the mask film is stripped to open diode contact areas on both sides of wafers. Next high melting point metal and low melting point metal films are selectively electroplated on all open silicon surfaces. Stacking is performed on wafer level by bonding of desired wafer count by solid-liquid interdiffusion process. Wafer stacks are sawed into individual stacked diode dies along outer slopes of V-grooves. Final stacked devices can be used as DSRDdrift step recovery diodes. Compared to DSRDs made by known methods, better fabrication yield and higher pulse power electrical performance is achieved.

Monolithic integration of low-capacitance p-n junctions and low-resistance p-n junctions (when conducting in reverse bias) is provided. Three epitaxial layers are used. The low-capacitance junctions are formed by the top two epitaxial layers. The low-resistance p-n junction is formed in the top epitaxial layer, and two buried structures at interfaces between the three epitaxial layers are used to provide a high doping region that extends from the low-resistance p-n junction to the substrate, thereby providing low resistance to current flow. The epitaxial layers are lightly doped as required by the low-capacitance junction design, so the buried structures are needed for the low-resistance p-n junction. The high doping region is formed by diffusion of dopants from the substrate and from the buried structures during thermal processing.

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.

It is provided a semiconductor device comprising a power line, a Silicon-on-Insulator, SOI, substrate comprising a semiconductor layer and a semiconductor bulk substrate comprising a first doped region, a first transistor device formed in and above the SOI substrate and comprising a first gate dielectric formed over the semiconductor layer and a first gate electrode formed over the gate dielectric, a first diode electrically connected to the first gate electrode and a second diode electrically connected to the first diode and the power line; and wherein the first and second diodes are partially formed in the first doped region.

A semiconductor structure includes a semiconductor substrate having a first electrical portion, a second electrical portion, and a bridged conductive layer. The first electrical portion includes a first semiconductor well, a second semiconductor well in the first semiconductor well, and a third semiconductor well and a fourth semiconductor well in the second semiconductor well. The second electrical portion includes a fifth semiconductor well, a semiconductor layer in the fifth semiconductor well, and a sixth semiconductor well and a seventh semiconductor well in the fifth semiconductor well. The semiconductor layer has separated first and second portions. The bridged conductive layer connects the fourth semiconductor well and the sixth semiconductor well.

According to an embodiment of the present invention, a method for fabricating a semiconductor device comprises depositing a transition layer on a substrate, depositing GaN material on the transition layer, forming a contact on the GaN material, depositing a stressor layer on the GaN material, separating the transition layer and the substrate from the GaN material, patterning and removing portions of the GaN material to expose portions of the stressor layer.

A super junction MOSFET 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.sup. region with a lower impurity concentration than the n-type drift region. With this structure, it is possible to provide a super junction MOSFET which prevents a sharp rise in hard recovery waveform during a reverse recovery operation.

The present invention relates generally to high current density access devices (ADs), and more particularly, to a structure and method of forming tunable voltage margin access diodes in phase change memory (PCM) blocks using layers of copper-containing mixed ionic-electronic conduction (MIEC) materials. Embodiments of the present invention may use layers MIEC material to form an access device that can supply high current-densities and operate reliably while being fabricated at temperatures that are compatible with standard BEOL processing. By varying the deposition technique and amount of MIEC material used, the voltage margin (i.e. the voltage at which the device turns on and the current is above the noise floor) of the access device may be tuned to specific operating conditions of different memory devices.

According to an embodiment of the present invention, a method for fabricating a semiconductor device comprises depositing a transition layer on a substrate, depositing GaN material on the transition layer, forming a contact on the GaN material, depositing a stressor layer on the GaN material, separating the transition layer and the substrate from the GaN material, patterning and removing portions of the GaN material to expose portions of the stressor layer.

A semiconductor device includes a first nitride semiconductor layer having a first region, a second nitride semiconductor layer that is on the first nitride semiconductor layer and contains carbon and silicon, a third nitride semiconductor layer that is on the second nitride semiconductor layer and has a second region, a fourth nitride semiconductor layer on the third nitride semiconductor layer, the fourth nitride semiconductor layer having a band gap that is wider than a band gap of the third nitride semiconductor layer, a source electrode that is on the fourth nitride semiconductor layer and is electrically connected to the first region, a drain electrode that is on the fourth nitride semiconductor layer and is electrically connected to the second region, and a gate electrode that is on the fourth nitride semiconductor layer and is between the source electrode and the drain electrode.