A method of manufacturing a semiconductor device that includes a junction field effect transistor, the junction field effect transistor including a semiconductor substrate of a first conductivity type, an epitaxial layer of the first conductivity type formed on the semiconductor substrate, a source region of the first conductivity type formed on a surface of the epitaxial layer, a channel region of the first conductivity type formed in a lower layer of the source region, a pair of trenches formed in the epitaxial layer so as to sandwich the source region therebetween, and a pair of gate regions of a second conductivity type, opposite to the first conductivity type, formed below a bottom of the pair of trenches.

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.

A JFET having vertical and horizontal channel elements may be made from a semiconductor material such as silicon carbide using a first mask for multiple implantations to form a horizontal planar JFET region comprising a lower gate, a horizontal channel, and an upper gate, all above a drift region resting on a drain substrate region, such that the gates and horizontal channel are self-aligned with the same outer size and outer shape in plan view. A second mask may be used to create a vertical channel region abutting the horizontal channel region. The horizontal channel and vertical channel may each have multiple layers with varying doping concentrations. Angled implantations may use through the first mask to implant portions of the vertical channel regions. The window of the second mask may partially overlap the horizontal JFET region to insure abutment of the vertical and horizontal channel regions.

A JFET has a semiconductor body with a first surface and second surface substantially parallel to the first surface. A source metallization and gate metallization are arranged on the first surface. A drain metallization is arranged on the second surface. In a sectional plane substantially perpendicular to the first surface, the semiconductor body includes: a first semiconductor region in ohmic contact with the source and drain metallizations, at least two second semiconductor regions in ohmic contact with the gate metallization, spaced apart from one another, and forming respective first pn-junctions with the first semiconductor region, and at least one body region forming a second pn-junction with the first semiconductor region. The at least one body region is in ohmic contact with the source metallization. At least a portion of the at least one body region is, in a projection onto the first surface, arranged between the two second semiconductor regions.

An integrated circuit of the BiCMOS type includes at least one vertical junction field-effect transistor. The vertical junction field-effect transistor is formed to include a channel region having a critical dimension of active surface that is controlled by photolithography.

A III-N-based vertical transistor includes a III-N substrate, a source, a drain, and a channel comprising a III-N crystal material and extending between the source and the drain. The channel includes at least one sidewall surface aligned 0.3 with respect to an m-plane of the III-N crystal material. The III-N-based vertical transistor also includes a gate electrically coupled to the at least one sidewall surface of the channel.

A method of manufacturing a vertical junction field effect transistor (JFET) includes forming a drain in a semiconductor substrate, forming a compound semiconductor epitaxial layer on the semiconductor substrate, and forming a source, a gate, a drift region, and a body diode all in the same compound semiconductor epitaxial layer. The drain is vertically spaced apart from the source and the gate by the drift region. The body diode is connected between the drain and the source.

A semiconductor component includes semiconductor fins formed between a base plane and a main surface of a semiconductor body. Each semiconductor fin includes a source region formed between the main surface and a channel/body region, and a drift zone formed between the channel/body region and the base plane. The semiconductor component further includes gate electrode structures on two mutually opposite sides of each channel/body region, and a field electrode structure between mutually adjacent ones of the semiconductor fins. Each field electrode structure is separated from the drift zone by a field dielectric and extends from the main surface as far as the base plane. The gate electrode structures assigned to the mutually adjacent semiconductor fins enclose an upper portion of the corresponding field electrode structure from two sides.

A JFET is formed with vertical and horizontal elements made from a high band-gap semiconductor material such as silicon carbide via triple implantation of a substrate comprising an upper drift region and a lower drain region, the triple implantation forming a lower gate, a horizontal channel, and an upper gate, in a portion of the drift region. A source region may be formed through a portion of the top gate, and the top and bottom gates are connected. A vertical channel region is formed adjacent to the planar JFET region and extending through the top gate, horizontal channel, and bottom gate to connect to the drift, such that the lower gate modulates the vertical channel as well as the horizontal channel, and current from the sources flows first through the horizontal channel and then through the vertical channel into the drift.

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.