An ESD protection device including a Si substrate with an ESD protection circuit formed at the surface of the substrate; pads formed on the Si substrate; a rewiring layer opposed to the surface of the Si substrate, which includes terminal electrodes electrically connected to the pads. The rewiring layer includes a SiN protection film formed on the surface of the Si substrate to cover parts of the pads except regions in contact with openings (contact holes) formed in a resin layer, and the resin layer that is lower in dielectric constant than the SiN protection film, and formed between the SiN protection film and the terminal electrodes. Thus, provided is a semiconductor device which can reduce the generation of parasitic capacitance, and eliminates variation in parasitic capacitance generated.

A junction barrier Schottky rectifier with first and second drift layer sections, wherein a peak net doping concentration of the first section is at least two times lower than a minimum net doping concentration of the second section. For each emitter region the first section includes a layer which is in contact with the respective emitter region to form a pn-junction between the first section and the respective emitter region, wherein the thickness of this layer in a direction perpendicular to the interface between the first section and the respective emitter region is at least 0.1 m. The JBS rectifier has a transition from unipolar to bipolar conduction mode at a lower forward bias due to lowering of electrostatic forces otherwise impairing the transport of electrons toward the emitter regions under forward bias conditions, and with reduced snap-back phenomenon.

A transient voltage suppressing (TVS) device formed in an epitaxial layer of a first conductivity type supported on a semiconductor substrate. The TVS device further comprises a plurality of contact trenches opened and extended to a lower part of the epitaxial layer filled with a doped polysilicon layer of a second conductivity type wherein the trenches are further surrounded by a heavy dopant region of the second conductivity type. The TVS device further includes a metal contact layer disposed on a top surface of the epitaxial layer electrically connected to a Vcc electrode wherein the metal contact layer further directly contacting the doped polysilicon layer and the heavy dopant region of the second conductivity type.

Connection patterns of plural diodes include a first series connection pattern and a second series connection pattern. The first series connection pattern extends from an input terminal in the X direction. The second series connection pattern has a portion through which a current flows to approach the input terminal. The first series connection pattern includes a first diode, which is the first diode counted from the input terminal. The second series connection pattern includes a second diode, which is the last diode counted from the input terminal. The second diode is disposed separately from the first diode with some distance therebetween in the Y direction. An N-type region of the first diode and a P-type region of the second diode directly oppose each other as viewed in a planar direction.

A vertical tunneling FET (TFET) provides low-power, high-speed switching performance for transistors having critical dimensions below 7 nm. The vertical TFET uses a gate-all-around (GAA) device architecture having a cylindrical structure that extends above the surface of a doped well formed in a silicon substrate. The cylindrical structure includes a lower drain region, a channel, and an upper source region, which are grown epitaxially from the doped well. The channel is made of intrinsic silicon, while the source and drain regions are doped in-situ. An annular gate surrounds the channel, capacitively controlling current flow through the channel from all sides. The source is electrically accessible via a front side contact, while the drain is accessed via a backside contact that provides low contact resistance and also serves as a heat sink. Reliability of vertical TFET integrated circuits is enhanced by coupling the vertical TFETs to electrostatic discharge (ESD) diodes.

An integrated circuit with a shallow trench isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode. An integrated circuit with a gate space isolated, low capacitance, ESD protection diode in parallel with a shallow trench isolated, low capacitance, ESD protection diode.

According to one embodiment, a semiconductor device is provided. The semiconductor device has a first region formed of semiconductor and a second region formed of semiconductor which borders the first region. An electrode is formed to be in ohmic-connection with the first region. A third region is formed to sandwich the first region. A first potential difference is produced between the first and the second regions in a thermal equilibrium state, according to a second potential difference between the third region and the first region.

Diodes for use in FinFET technologies having increased junction electric fields without the need for increased dopant concentrations, as well as methods, apparatus, and systems for fabricating such diodes. The diodes may comprise a semiconductor substrate and a plurality of fins formed on the semiconductor substrate; wherein each of the plurality of fins comprises an N channel doped region comprising an N channel dopant, and the semiconductor substrate further comprises a plurality of P channel doped regions comprising a P channel dopant, wherein each of the P channel doped regions is disposed under one of the plurality of fins and is adjacent to the N channel doped region of the fin.

A robust electrostatic (ESD) protection device is provided. In one example, the ESD protection device is configured to accommodate three nodes. When used with a differential signal device, the first and second nodes may be coupled with the differential signal device's BP and BM signal lines, respectively, and the third node may be coupled to a voltage source. This allows for a single ESD protection device to be used to protect the signal lines of the differential signal device, thus providing significant substrate area savings as compared to the conventional means of using three dual-node ESD protection devices to accomplish substantially the same protection mechanism. Moreover, the ESD protection device may be structurally designed to handle high voltage ESD events, as required by the FlexRay standard.

A semiconductor package in an embodiment includes a semiconductor device which has a first semiconductor element, a second semiconductor element, and a common first electrode between the first and second semiconductor elements. A second electrode is electrically connected to the first semiconductor element. A third electrode extends through the second semiconductor element and electrically connects to the first electrode. A fourth electrode is electrically connected to the second semiconductor element. A first terminal of the package is electrically connected to the third electrode. A second terminal of the package is electrically connected to the second electrode and the fourth electrode. An insulating material surrounds the semiconductor device.