An electrostatic discharge protection clamp includes a substrate and a first electrostatic discharge protection device over the substrate. The first electrostatic discharge protection device includes a buried layer over the substrate. The buried layer has a first region having a first doping concentration and a second region having a second doping concentration. The first doping concentration is greater than the second doping concentration. The first electrostatic discharge protection device includes a first transistor over the buried layer. The first transistor has an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp. The first electrostatic discharge protection device includes a second transistor over the buried layer. The second transistor has an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp. A collector of the first transistor and a collector of the second transistor are over the first region of the buried layer.

A semiconductor device includes a semiconductor substrate, a collector region formed within the semiconductor substrate in a first semiconductor region having an upper surface and a collector sidewall, a base region disposed over the collector region, a seed region formed over the semiconductor substrate and coupled to the semiconductor substrate outside the base region, an extrinsic base region having an upper surface and formed over the seed region and electrically coupled to the base region, and an emitter region formed over the base region.

A method is presented for forming a monolithically integrated semiconductor device. The method includes forming a first device including first hydrogenated silicon-based contacts formed on a first portion of a semiconductor material of an insulating substrate and forming a second device including second hydrogenated silicon-based contacts formed on a second portion of the semiconductor material of the insulating substrate. Source and drain contacts of the first device are formed before a gate contact of the first device and a gate contact of the second device is formed before the emitter and collector contacts of the second device. The first device can be a heterojunction field effect transistor (HJFET) and the second device can be a (heterojunction bipolar transistor) HBT. The HJFET and the HBT are integrated in a neuronal circuit and create negative differential resistance by forming a lambda diode.

A semiconductor device and a manufacturing method thereof are provided. The semiconductor device includes a substrate, a first well, a second well, and first and second doped regions. The substrate has heavily doped and lightly doped regions. The lightly doped region is disposed over the heavily doped region. The first well is disposed in the lightly doped region. The first well has a conductive type complementary to a conductive type of the heavily doped and lightly doped regions. The second well is disposed in the substrate over the lightly doped region. A location of the first well overlaps a location of the second well. The first and the second doped regions are located in the second well within the active region, and spaced apart from each other. The first and the second doped regions have a same conductive type complementary to a conductive type of the second well.

A bipolar junction transistor (BJT) containing sensor that includes a vertically oriented stack of an emitter overlying a supporting substrate, a base region present directly atop the emitter and a collector atop the base region. A first extrinsic base region is in contact with a first sidewall of a vertically oriented base region. The first extrinsic base region is electrically contacted to provide the bias current of the bipolar junction transistor during sensor operation. A second extrinsic base region is in contact with a second sidewall of the base region. The second extrinsic base region includes a sensing element. A sample trench is present adjacent to the BJT having a trench sidewall provided by the sensing element.

Provided is a semiconductor device including a substrate having a P-type conductivity, a buried layer having an N-type conductivity, an NPN bipolar junction transistor (BJT), and a first well region having the P-type conductivity. The buried layer is located on the substrate. The NPN BJT is located on the buried layer. The first well region is located between the buried layer and the NPN BJT. The NPN BJT is separated from the buried layer by the first well region.

Disclosed examples provide fabrications methods and integrated circuits with back ballasted NPN bipolar transistors which include an n-type emitter in a P doped region, a p-type base with a first side facing the emitter, and an n-type collector laterally spaced from a second side of the base, where the collector includes a first side facing the second side of the base, an opposite second side, a silicided first collector portion and a silicide blocked second collector portion covered with a non-conductive dielectric that extends laterally between the first collector portion and the second side of the collector to provide back side ballasting for lateral breakdown and low current conduction via a deep N doped region while the vertical NPN turns on at a high voltage.

An n-type region and a p-type region of a first parallel pn layer are arranged parallel to a base front surface, in a striped planar layout extending from an active region over an edge termination region. In the n-type region, a gate trench extending linearly along a first direction is provided. In an intermediate region, in a surface region on the base front surface side of the first parallel pn layer, a second parallel pn layer is provided. The second parallel pn layer is arranged having a repetition cycle shifted along a second direction a cell with respect to a repetition cycle of the n-type region and the p-type region of the first parallel pn layer. A gate trench termination portion terminates in the intermediate region between the active region and the edge termination region, and is covered by the p-type region of the second parallel pn layer.

A method includes implanting dopant of a first conductivity type into an epitaxial layer of semiconductor material to form first and second false collector regions adjacent to the surface of the epitaxial layer. The first false collector region is located laterally on a first side of a base region. The base region is formed within the epitaxial layer from dopant of a second conductivity type that is opposite the first conductivity type. The second false collector region is located laterally on a second side of the base region. The second side is opposite the first side of the base region. The base region is a base of a parasitic bipolar junction in an isolation region of an active semiconductor device.

A heterojunction bipolar transistor includes a collector layer, a base layer, an emitter layer, and a ballast resistance layer. The collector layer is made of an n-type compound semiconductor material. The base layer is disposed on the collector layer and is made of a p-type compound semiconductor material. The emitter layer is disposed on the base layer and is made of an n-type compound semiconductor material having a band gap larger than a band gap of the base layer. The ballast resistance layer is disposed on the emitter layer and is made of an intrinsic or p-type compound semiconductor material.