A method of producing a four-layer silicon diode, including selecting a first silicon wafer, wherein said first silicon wafer is CZ-grown B-doped with <100> orientation, a resistivity of less than 0.01 Ohm-cm, and an oxygen content of greater than 10 ppma, and then selecting a second silicon wafer, wherein said second silicon wafer is CZ-grown P-doped with <100> orientation, a resistivity of less than 0.005 Ohm-cm, and an oxygen content of greater than 10 ppma, followed by cleaning the respective first and second silicon wafers. The wafers are then HF treated to yield respective first and second cleaned wafers, the first cleaned wafer is positioned into a first furnace and the second cleaned wafer is positioned into a second furnace, wherein the first and second furnaces are not unitary. Next is annealing the respective first and second cleaned wafers in a reducing atmosphere to yield respective first and second respective out-diffused gradient wafers, followed by bonding together respective first and second heat-treated wafers to yield a mated and/or bonded four-layer substrate having a first heavy doped n-type layer, a second gradient doped n-type layer, a third gradient doped p-type layer, and a fourth heavy doped p-type layer.

A semiconductor element capable of adjusting a barrier height ϕ.sub.Bn and performing zero-bias operation and impedance matching with an antenna for improving detection sensitivity of high-frequency RF electric signals, a method of manufacturing the same, and a semiconductor device having the same. In the semiconductor element, a concentration of InGaAs (n-type InGaAs layer) is intentionally set to be high over a range for preventing the “change of the barrier height caused by the bias” described above up to a deep degeneration range. An electron Fermi level (E.sub.F) increases from a band edge of InGaAs (n-type InGaAs layer) to a band edge of InP (InP depletion layer).

An electrostatic discharge (ESD) protection device is provided. The ESD protection device includes a substrate, an active region, a first terminal region, and a second terminal region. The substrate includes dopants having a first dopant conductivity. The active region is arranged over the substrate and has an upper surface. The first terminal region and the second terminal region are arranged in the active region laterally spaced apart from each other. The first terminal region and the second terminal region each include a well region having dopants of the first dopant conductivity and a first doped region arranged in the well region. The first doped region includes dopants having a second dopant conductivity.

A gallium nitride power device, including: a gallium nitride substrate; cathodes; a plurality of gallium nitride protruding structures arranged on the gallium nitride substrate and between the cathodes, a groove is formed between adjacent gallium nitride protruding structures; an electron transport layer, covering a top portion and side surfaces of each of the gallium nitride protruding structures; a gallium nitride layer, arranged on the electron transport layer and filling each of the grooves; a plurality of second conductivity type regions, where each of the second conductivity type regions extends downward from a top portion of the gallium nitride layer into one of the grooves, and the top portion of each of the gallium nitride protruding structures is higher than a bottom portion of each of the second conductivity type regions; and an anode, arranged on the gallium nitride layer and the second conductivity type regions.

Aspects of the disclosure provide a semiconductor device and method of manufacturing. Embodiments of the disclosure enable placing of protective structures without modifying spacing rules. The device includes a first device region defined above a substrate, the first device region being isolated from the substrate by a buried insulating layer. The first device region includes a first power rail, a first signal line traversing at least a first portion of the first device region, and a first plurality of edge cells positioned in the substrate adjacent the first device region. A first edge cell includes a substrate contact connecting the first power rail to the substrate and a first signal line antenna diode connecting the first signal line to the substrate.

A semiconductor device and a method of forming the same are provided. The semiconductor device includes a first substrate, a capacitor within the first substrate, a diode structure within the first substrate adjacent the capacitor, and a first interconnect structure over the capacitor and the diode structure. A first conductive via of the first interconnect structure electrically couples the capacitor to the diode structure.

The present invent provides a method comprising forming a first wafer comprising a first substrate of a group IV semiconductor, and a group III-V semiconductor device structure formed by selective area epitaxial growth on a surface portion of a front side of the first substrate. The method further comprises forming a second wafer comprising a second substrate of a group IV semiconductor, and a group IV semiconductor device structure formed on a front side of the second substrate, and bonding the first wafer to the second wafer with the front side of the first substrate facing the front side of the second wafer.

A method for manufacturing a merged PiN Schottky (MPS) diode may include steps of providing a substrate having a first conductivity type; forming an epitaxial layer with the first conductivity type on top of the substrate; forming a plurality of regions with a second conductivity type under a top surface of the epitaxial layer; forming a plasma spreading layer; depositing and patterning a first Ohmic contact metal on the regions with the second conductivity type; depositing a Schottky contact metal on top of the entire epitaxial layer; and forming a second Ohmic contact metal on a backside of the substrate. In another embodiment, the step of forming a plurality of regions with a second conductivity type may include steps of depositing and patterning a mask layer on the epitaxial layer, implanting P-type dopant into the epitaxial layer, and removing the mask layer.

A transient voltage suppression device and a manufacturing method therefor, the transient voltage suppression device including: a substrate, a first conductivity type well region and a second conductivity type well region disposed in the substrate. The first conductivity type well region includes a first well, a second well, and a third well. The second conductivity type well region includes a fourth well that isolates the first well from the second well, and a fifth well that isolates the second well from the third well. The device further includes a Zener diode well region provided in the first well, a first doped region provided in the Zener diode well region, a second doped region provided in the Zener diode well region, a third doped region provided in the second well, a fourth doped region provided in the third well, and a fifth doped region provided in the third well.

An object of the present invention is to provide stable withstand voltage characteristics, reduce turn-off losses along with a reduction in leakage current when the device is off, improve controllability of turn-off operations, and improve blocking capability at turn-off. An N buffer layer includes a first buffer layer joined to an active layer and having one peak in impurity concentration, and a second buffer layer joined to the first buffer layer and an N.sup.− drift layer, having at least one peak point in impurity concentration, and having a lower maximum impurity concentration than the first buffer layer. The impurity concentration at the peak point of the first buffer layer is higher than the impurity concentration of the N.sup.− drift layer, and the impurity concentration of the second buffer layer is higher than the impurity concentration of the N.sup.− drift layer in the entire area of the second buffer layer.