A junction field effect transistor (JFET) structure includes a doped polysilicon gate over a channel region of a semiconductor layer. The doped polysilicon gate has a first doping type. A raised epitaxial source is on the source region of the semiconductor layer and adjacent a first sidewall of the doped polysilicon gate, and has a second doping type opposite the first doping type. A raised epitaxial drain is on the drain region of the semiconductor layer and adjacent a second sidewall of the doped polysilicon gate, and has the second doping type. A doped semiconductor region is within the channel region of the semiconductor layer and extending from the source region to the drain region, and a non-conductive portion of the semiconductor layer is within the channel region to separate the doped semiconductor region from the doped polysilicon gate.

A process of fabricating semiconductor devices includes determining a correlation between band gap and long range order parameter for one or more stoichiometries. Semiconductor materials having a preselected (target) band gap can be fabricated by controlling process parameters to form a material having a stoichiometry and long range order parameter having the target band gap.

Germanium-based sensors are disclosed herein. An exemplary germanium-based sensor includes a germanium photodiode and a junction field effect transistor (JFET) formed from a germanium layer disposed on and/or in a silicon substrate. A doped silicon layer, which can be formed by in-situ doping epitaxially grown silicon, is disposed between the germanium layer and the silicon substrate. In embodiments where the germanium layer is on the silicon substrate, the doped silicon layer is disposed between the germanium layer and an oxide layer. The JFET has a doped polysilicon gate, and in some embodiments, a gate diffusion region is disposed in the germanium layer under the doped polysilicon gate. In some embodiments, a pinned photodiode passivation layer is disposed in the germanium layer. In some embodiments, a pair of doped regions in the germanium layer is configured as an e-lens of the germanium-based sensor.

Organosilicon chemistry, polymer derived ceramic materials, and methods. Such materials and methods for making polysilocarb (SiOC) and Silicon Carbide (SiC) materials having 3-nines, 4-nines, 6-nines and greater purity. Processes and articles utilizing such high purity SiOC and SiC.

The semiconductor device includes: an epitaxial layer of a first conductivity type formed on a first principal surface of a semiconductor substrate; a first semiconductor region of the first conductivity type formed from an outermost surface to an inner portion of the epitaxial layer; and a third semiconductor region of a second conductivity type formed from a bottom surface of the first semiconductor region to an inner portion of the semiconductor substrate. The method includes: (a) polishing a second principal surface opposite to the first principal surface of the semiconductor substrate above which at least a source region, a drain region, and a gate electrode are formed to thin the substrate; and (b) ion-implanting impurities of the second conductivity type from the second principal surface of the polished semiconductor substrate to form the third semiconductor region.

Semiconductor devices comprising a getter material are described. The getter material can be located in or over the active region of the device and/or in or over a termination region of the device. The getter material can be a conductive or an insulating material. The getter material can be present as a continuous or discontinuous film. The device can be a SiC semiconductor device such as a SiC vertical MOSFET. Methods of making the devices are also described. Semiconductor devices and methods of making the same comprising source ohmic contacts formed using a self-aligned process are also described. The source ohmic contacts can comprise titanium silicide and/or titanium silicide carbide and can act as a getter material.

An IC with a split-gate transistor includes a substrate doped the second conductivity type having a semiconductor surface layer doped the first conductivity type. The transistor includes a first doped region formed as an annulus, a second doped region including under the first doped region, and a third doped region under the second doped region, all coupled together and doped the second conductivity type. A fourth doped region doped the first conductivity type is above the third doped region. A fifth doped region doped the first conductivity type is outside the annulus. Sixth doped regions doped the first conductivity type include a first sixth doped region surrounded by the annulus in the semiconductor surface layer and a second sixth doped region in the fifth doped region. Field oxide includes a field oxide portion between the fifth and the first doped region. A field plate is on the field oxide portion.

A semiconductor device includes a layer stack with a plurality of first semiconductor layers of a first doping type and a plurality of second semiconductor layers of a second doping type complementary to the first doping type. The first and second semiconductor layers are arranged alternatingly between first and second surfaces of the layer stack. A first semiconductor region of a first semiconductor device adjoins the first semiconductor layers. Each of at least one second semiconductor region of the first semiconductor device adjoins at least one of the plurality of second semiconductor layers, and is spaced apart from the first semiconductor region. Each of at least one barrier layer configured to form a diffusion barrier is arranged in parallel to the first surface and to the second surface and adjacent to one of the first semiconductor layers, or adjacent to one of the second semiconductor layers, or both.

Semiconductor devices comprising a getter material are described. The getter material can be located in or over the active region of the device and/or in or over a termination region of the device. The getter material can be a conductive or an insulating material. The getter material can be present as a continuous or discontinuous film. The device can be a SiC semiconductor device such as a SiC vertical MOSFET. Methods of making the devices are also described. Semiconductor devices and methods of making the same comprising source ohmic contacts formed using a self-aligned process are also described. The source ohmic contacts can comprise titanium silicide and/or titanium silicide carbide and can act as a getter material.

An IC with a split-gate transistor includes a substrate doped the second conductivity type having a semiconductor surface layer doped the first conductivity type. The transistor includes a first doped region formed as an annulus, a second doped region including under the first doped region, and a third doped region under the second doped region, all coupled together and doped the second conductivity type. A fourth doped region doped the first conductivity type is above the third doped region. A fifth doped region doped the first conductivity type is outside the annulus. Sixth doped regions doped the first conductivity type include a first sixth doped region surrounded by the annulus in the semiconductor surface layer and a second sixth doped region in the fifth doped region. Field oxide includes a field oxide portion between the fifth and the first doped region. A field plate is on the field oxide portion.