A method for manufacturing a display panel comprising light emitting device including micro LEDs includes providing multiple donor wafers having a surface region and forming an epitaxial material overlying the surface region. The epitaxial material includes an n-type region, an active region comprising at least one light emitting layer overlying the n-type region, and a p-type region overlying the active layer region. The multiple donor wafers are configured to emit different color emissions. The epitaxial material on the multiple donor wafers is patterned to form a plurality of dice, characterized by a first pitch between a pair of dice less than a design width. At least some of the dice are selectively transferred from the multiple donor wafers to a common carrier wafer such that the carrier wafer is configured with different color emitting LEDs. The different color LEDs could comprise red-green-blue LEDs to form a RGB display panel.

A JFET is formed with vertical and horizontal elements made from a high band-gap semiconductor material such as silicon carbide via triple implantation of a substrate comprising an upper drift region and a lower drain region, the triple implantation forming a lower gate, a horizontal channel, and an upper gate, in a portion of the drift region. A source region may be formed through a portion of the top gate, and the top and bottom gates are connected. A vertical channel region is formed adjacent to the planar JFET region and extending through the top gate, horizontal channel, and bottom gate to connect to the drift, such that the lower gate modulates the vertical channel as well as the horizontal channel, and current from the sources flows first through the horizontal channel and then through the vertical channel into the drift.

A semiconductor device includes a semiconductor layer laminate disposed on a semiconductor substrate, a first and a second low-side transistors, and a first and a second high-side transistors. Each of the transistors is disposed on the semiconductor layer laminate, and includes a gate electrode, a source electrode, and a drain electrode. The second low-side transistor is disposed between the first low-side transistor and the first high-side transistor, and the first high-side transistor is disposed between the second low-side transistor and the second high-side transistor. The source electrodes of the first and the second low-side transistors are combined into one source electrode, the drain electrodes of the first and the second high-side transistors are combined into one drain electrode, and the drain electrode of the second low-side transistor and the source electrode of the first high-side transistor are combined into one first electrode.

A nitride semiconductor device according to the present disclosure includes a substrate, a p-type GaN layer formed on a main surface of the substrate and made of Al.sub.xIn.sub.yGa.sub.1-x-yN containing p-type impurities, where 0X<1, 0Y<1, and a Ti film formed on the p-type GaN layer. The Ti film is in a coherent or metamorphic state with respect to the p-type GaN layer.

Components can be damaged if they are exposed to excess voltages. A device is disclosed herein which can be placed in series with a component and a node that may be exposed to high voltages. If the voltage becomes too high, the device can autonomously switch into a relatively high impedance state, thereby protecting the other components.

Aspects of the present disclosure provides a device comprising a P-type semiconductor substrate, an N-type tub above the semiconductor substrate, a P-type region provided in the N-type tub isolated by one or more P-type isolation structures, and an N-type punch-through stopper provided under the P-type regions isolated by the isolation structure(s). The punch-through stopper is heavily doped compared to the N-type tub. The P-type region has a width between the two isolation structures that is equal to or less than that of the N-type punch-through stopper.

A vertical JFET with a ladder termination may be made by a method using a limited number of masks. A first mask is used to form mesas and trenches in active cell and termination regions simultaneously. A mask-less self-aligned process is used to form silicide source and gate contacts. A second mask is used to open windows to the contacts. A third mask is used to pattern overlay metallization. An optional fourth mask is used to pattern passivation. Optionally the channel may be doped via angled implantation, and the width of the trenches and mesas in the active cell region may be varied from those in the termination region.

A method of fabricating a multi-layer epitaxial buffer layer stack for transistors includes depositing a buffer stack on a substrate. A first voided Group IIIA-N layer is deposited on the substrate, and a first essentially void-free Group IIIA-N layer is then deposited on the first voided Group IIIA-N layer. A first high roughness Group IIIA-N layer is deposited on the first essentially void-free Group IIIA-N layer, and a first essentially smooth Group IIIA-N layer is deposited on the first high roughness Group IIIA-N layer. At least one Group IIIA-N surface layer is then deposited on the first essentially smooth Group IIIA-N layer.

The present invention relates to a junction field effect transistor. The junction field effect transistor comprises a substrate (10), a buried layer in the substrate, a first well region (32) and a second well region (34) that are on the buried layer, a source lead-out region (50), a drain lead-out region (60), and a first gate lead-out region (42) that are in the first well region (32), and a second gate lead-out region (44) in the second well region (34). A Schottky junction interface (70) is disposed on the surface of the first well region (32). The Schottky junction interface (70) is located between the first gate lead-out region (42) and the drain lead-out region (60), and is isolated from the first gate lead-out region (42) and the drain lead-out region (60) by means of isolation structures. The present invention also relates to a manufacturing method for a junction field effect transistor.

The switching device includes an electron transport layer; an electron supply layer provided on the electron transport layer and being in contact with the electron transport layer by heterojunction; a source electrode being in contact with the electron supply layer; a drain electrode being in contact with the electron supply layer at a position spaced from the source electrode; and a first gate electrode provided above the electron supply layer, and provided between the source electrode and the drain electrode when viewed in a plan view from above. The first gate electrode is electrically connected above the electron supply layer to the drain electrode. An on-resistance of the switching device is lower than an electric resistance between the first gate electrode and the drain electrode.