A neuromorphic device for the analog computation of a linear combination of input signals, for use, for example, in an artificial neuron. The neuromorphic device provides non-volatile programming of the weights, and fast evaluation and programming, and is suitable for fabrication at high density as part of a plurality of neuromorphic devices. The neuromorphic device is implemented as a vertical stack of flash-like cells with a common control gate contact and individually contacted source-drain (SD) regions. The vertical stacking of the cells enables efficient use of layout resources.

Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed JFET includes a vertical channel region located in a mesa and a first channel control region located on a first side of the mesa. The first channel control region is at least one of a gate region and a first base region. The JFET also includes a second base region located on a second side of the mesa and extending through the mesa to contact the vertical channel region. The vertical channel can be an implanted vertical channel. The vertical channel can be asymmetrically located in the mesa towards the first side of the mesa.

A method for manufacturing a vertical JFET includes providing a III-nitride substrate having a first conductivity type; forming a first III-nitride layer coupled to the III-nitride substrate, wherein the first III-nitride layer is characterized by a first dopant concentration and the first conductivity type; forming a plurality of trenches within the first III-nitride layer, wherein the plurality of trenches extend to a predetermined depth; epitaxially regrowing a second III-nitride structure in the trenches, wherein the second III-nitride structure is characterized by a second conductivity type; forming a plurality of III-nitride fins, each coupled to the first III-nitride layer, wherein the plurality of III-nitride fins are separated by one of a plurality of recess regions; epitaxially regrowing a III-nitride gate layer in the recess regions, wherein the III-nitride gate layer is coupled to the second III-nitride structure, and wherein the III-nitride gate layer is characterized by the second conductivity type.

Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed JFET includes a vertical channel region located in a mesa and a first channel control region located on a first side of the mesa. The first channel control region is at least one of a gate region and a first base region. The JEFT also includes a second base region located on a second side of the mesa and extending through the mesa to contact the vertical channel region. The vertical channel can be an implanted vertical channel. The vertical channel can be asymmetrically located in the mesa towards the first side of the mesa.

A field-effect transistor includes an n-type semiconductor layer that includes a Ga.sub.2O.sub.3-based single crystal and a plurality of trenches opening on one surface, a gate electrode buried in each of the plurality of trenches, a source electrode connected to a mesa-shaped region between adjacent trenches in the n-type semiconductor layer, and a drain electrode directly or indirectly connected to the n-type semiconductor layer on an opposite side to the source electrode.

A precursor for a vertical semiconductor device is provided with a substrate, a drift region over the substrate, and an upper precursor region over the drift region. The top surface of the precursor is substantially planar, and the substrate and the drift region are doped with a first dopant of a first polarity. In a first embodiment, a series of implants with a second dopant is provided in the upper precursor region via the top surface to form each of at least two gate regions such that each implant of the series of implants is provided at a different depth below the top surface. In a second embodiment, a series of implants with the first dopant is provided in the upper precursor region via the top surface to form a channel region that has at least a portion between two gate regions.

A nitride semiconductor device includes: a substrate; a nitride semiconductor layer above the substrate; a high-resistance layer above the nitride semiconductor layer; a p-type nitride semiconductor layer above the high-resistance layer; a first opening penetrating through the p-type nitride semiconductor layer and the high-resistance layer to the nitride semiconductor layer; an electron transport layer and an electron supply layer covering an upper portion of the p-type nitride semiconductor layer and the first opening; a gate electrode above the electron supply layer; a source electrode in contact with the electron supply layer; a second opening penetrating through the electron supply layer and the electron transport layer to the p-type nitride semiconductor layer; a potential fixing electrode in contact with the p-type nitride semiconductor layer at a bottom part of the second opening; and a drain electrode.

Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed four terminal JFET includes an integrated high voltage capacitor (HVC). The JFET includes a first terminal coupled to a drain region, a second terminal coupled to the source region, a third terminal coupled to the base region, and an integrated HVC terminal coupled to an integrated HVC electrode which forms an HVC with the drain region. The JFET also includes a channel formed by a channel region. A bias on the base region fully depletes the channel of majority carriers. The channel has an unbiased concentration of majority carriers. The integrated HVC electrode is positioned relative to the channel region such that applying the bias to the integrated HVC terminal depletes the channel by at most ten percent of the unbiased concentration of majority carriers.

A method for manufacturing a vertical JFET includes providing a III-nitride substrate having a first conductivity type and forming a first III-nitride layer coupled to the III-nitride substrate. The first III-nitride layer is characterized by a first dopant concentration and the first conductivity type. The method also includes forming a plurality of trenches within the first III-nitride layer and epitaxially regrowing a second III-nitride structure in the trenches. The second III-nitride structure is characterized by a second conductivity type. The method further includes forming a plurality of III-nitride fins, each coupled to the first III-nitride layer, wherein the plurality of III-nitride fins are separated by one of a plurality of recess regions, and epitaxially regrowing a III-nitride gate layer in the recess regions. The III-nitride gate layer is coupled to the second III-nitride structure and the III-nitride gate layer is characterized by the second conductivity type.

A silicon carbide substrate has a trench extending from a main surface of the silicon carbide substrate into the silicon carbide substrate. The trench has a trench width at a trench bottom. A shielding region is formed in the silicon carbide substrate. The shielding region extends along the trench bottom. In at least one doping plane extending approximately parallel to the trench bottom, a dopant concentration in the shielding region over a lateral first width deviates by not more than 10% from a maximum value of the dopant concentration. The first width is less than the trench width and is at least 30% of the trench width.