In one embodiment, an asymmetric TVS device may include a semiconductor substrate, comprising an inner region, the inner region having a first polarity, and a first surface region, disposed on a first surface of the semiconductor substrate, the first surface region comprising a second polarity, opposite the first polarity. The asymmetric TVS device may also include a second surface region, comprising the second polarity, and disposed on a second surface of the semiconductor substrate, opposite the first surface, wherein the first surface region comprises a first dopant concentration, and wherein the second surface region comprises a second dopant concentration, greater than the first dopant concentration.

Structures for a silicon-controlled rectifier and methods of forming a structure for a silicon-controlled rectifier. The structure includes a first well and a second well in a semiconductor substrate. The first well has a first conductivity type, and the second well has a second conductivity type opposite to the first conductivity type. The structure further includes a first terminal having a doped region that has a portion in the first well, and a second terminal including a second doped region that has a portion in the first well and a third doped region in the second well. The first and second doped regions have the second conductivity type, the third doped region has the first conductivity type, and the second doped region is positioned in a lateral direction between the first doped region and the third doped region.

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.

An emissive display device including LEDs, including a plurality of pixels, each including: an elementary control cell formed inside and on top of a semiconductor substrate; a first LED capable of emitting in a first wavelength range, arranged on the upper surface of the elementary control cell and having a first conduction region connected to a first connection pad of the elementary control cell; and a second LED capable of emitting in a second wavelength range, having a surface area smaller than that of the first LED, arranged on the upper surface of the first LED opposite a central region of the first LED, and having a first conduction region connected to a second connection pad of the elementary control cell via a first conductive via crossing the first LED.

The present disclosure provides a diode chip capable of attaining excellent electrical characteristics.

The present disclosure provides a diode chip (1), including: a semiconductor chip (10) having a first main surface (11); a first pin junction portion (31) formed on a surface of the first main surface (11) with a first polarity direction; a first diode pair (37) (rectifier pair) including a first pn junction portion (35) separated from the first pin junction portion (31) and formed in the semiconductor chip (10) with the first polarity direction and a first reversed pin junction portion (38) connected to the first pn junction portion (35) in reversed direction and formed on the first main surface (11) with a second polarity direction; and a first junction separation trench (46) formed on the first main surface (11) in a manner of separating the first pin junction portion (31) and the first diode pair (37).

Devices, methods and techniques are disclosed for providing a multi-layer diode without voids between layers. In one example aspect, a multi-stack diode includes at least two Drift Step Recovery Diodes (DSRDs). Each DSRD comprises a first layer having a first type of dopant, a second layer forming a region with at least ten times lower concentration of dopants compared to the adjacent layers, and a third layer having a second type of dopant that is opposite to the first type of dopant. The first layer of a second DSRD is positioned on top of the third layer of first DSRD. The first layer of the second DSRD and the third layer of the first DSRD are degenerate to form a tunneling diode at an interface of the first DSRD and second DSRD, the tunneling diode demonstrating a linear current-voltage characteristic.

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.

Structures for a silicon-controlled rectifier and methods of forming a structure for a silicon-controlled rectifier. The structure includes a first well and a second well in a semiconductor substrate. The first well has a first conductivity type, and the second well has a second conductivity type opposite to the first conductivity type. The structure further includes a first terminal having a doped region that has a portion in the first well, and a second terminal including a second doped region that has a portion in the first well and a third doped region in the second well. The first and second doped regions have the second conductivity type, the third doped region has the first conductivity type, and the second doped region is positioned in a lateral direction between the first doped region and the third doped region.

A bipolar semiconductor device includes at least a four-layer structure, a first main side with a first electrical contact, and a second main side with a second electrical contact separated from the first main side by at least a base layer of first conductivity type. A shorting layer of the first conductivity type is arranged on the second main side of the base layer. A third layer includes a patterned highly conductive material, such as metal and/or silicides, graphene, etc., and is deposited on the shorting. A fourth layer of the second conductivity type is arranged directly on the third layer, inserted between the shorting layer and the second electrical contact. This concept can be applied to any non-punch-through or punch-through reverse conducting IGBT designs, but is particularly effective for devices using thin wafers, and is also applicable to bipolar diodes in order to improve a soft recovery process.

ESD protection devices and methods are provided. In at least one embodiment, a device includes a first stack that forms a Zener diode. The first stack includes a substrate of a first conductivity type having a first region of a second conductivity type located therein. The first area is flush with a surface of the substrate. A second stack forms a diode and is located on and in contact with the surface of the substrate. The second stack includes a first layer of the second conductivity type having a second region of the first conductivity type located therein. The second area is flush, opposite the first stack, with the surface of the first layer. A third stack includes at least a second layer made of an oxygen-doped material, on and in contact with the second stack.