A circuit includes at least one bipolar transistor and at least one variable capacitance diode. The circuit is fabricated using a method whereby the bipolar transistor and variable capacitance diode are jointly produced on a common substrate.

A semiconductor device includes a semiconductor die, an N-doped region, an N-contact metal, a PN junction mesa, a P-contact metal, a first passivation layer, an anode feed metal, and a cathode feed metal. The semiconductor die may include a plurality of semiconductor layers disposed on an insulating substrate. The N-doped region may define an active area of the device. The N-contact metal may be disposed on a first portion of the N-doped region. The PN junction mesa may be disposed on a second portion of the N-doped region. The PN junction mesa may comprise a hyperabrupt N-doping layer disposed on the first portion of the N-doped region and a P-doped layer disposed on the hyperabrupt N-doping layer. The P-contact metal may be disposed on the P-doped layer of the PN junction mesa. The first passivation layer may cover the semiconductor layers of the semiconductor device and have openings for the N-contact metal and the P-contact metal. The anode feed metal may connect the P-contact metal to a first bond pad. The anode feed metal generally forms an arch from the P-contact metal to the first bond pad and the arch defines a space between the anode feed metal and the first passivation layer covering the semiconductor layers and a the of the PN junction mesa.

At least one bipolar transistor and at least one variable capacitance diode are jointly produced by a method on a common substrate.

A varactor structure includes a substrate. A first and second gate structure are disposed on the substrate. The first and second gate structures each include a base portion and a plurality of line portions connected thereto. The line portions of each of the first and second gate structures is alternately arranged. A meander diffusion region is formed in the substrate and surrounds the line portions. A first set of contact plugs is planned with at least two columns or rows and disposed on the base portions of the first and second gate structures. A second set of contact plugs is planned with at least two columns or rows and disposed on the meander diffusion region. A first conductive layer is disposed on a top end of the first set of contact plugs. A second conductive layer is disposed on a top end of the second set of contact plugs.

A semiconductor device may include a substrate and a hyper-abrupt junction region carried by the substrate. The hyper-abrupt region may include a first semiconductor layer having a first conductivity type, a first superlattice layer on the first semiconductor layer, a second semiconductor layer on the first superlattice layer and having a second conductivity type different than the first conductivity type, and a second superlattice layer on the second semiconductor layer. The semiconductor device may further include a gate dielectric layer on the second superlattice layer of the hyper-abrupt junction region, a gate electrode on the gate dielectric layer, and spaced apart source and drain regions adjacent the hyper-abrupt junction region.

A low noise device includes an isolation feature in a substrate. The low noise device further includes a gate stack over a channel in the substrate, wherein the isolation feature is adjacent to the channel. The low noise device further includes a spacer surrounding a portion of the gate stack, wherein an edge of the gate stack is spaced from an edge of the isolation feature adjacent to the spacer by a distance ranging from a minimum spacing distance to about 0.3 microns (μm).

A semiconductor device includes a first substrate having opposite first and second sides, a first conductive layer on the first side of the first substrate, and a second substrate having opposite first and second sides. The second side of the second substrate is bonded to the first side of the first substrate. The second substrate includes a semiconductor material, and at least one circuit element electrically coupled to the first conductive layer. The at least one circuit element includes at least one of a Schottky diode configured by the semiconductor material and a first contact structure, a capacitor having a first electrode of the semiconductor material, or a resistor of the semiconductor material.

At least one bipolar transistor and at least one variable capacitance diode are jointly produced by a method on a common substrate.

A low noise device includes an isolation feature in a substrate. The low noise device further includes a gate stack over a channel in the substrate, wherein the isolation feature is adjacent to the channel. The low noise device further includes a spacer surrounding a portion of the gate stack, wherein an edge of the gate stack is spaced from an edge of the isolation feature adjacent to the spacer by a distance ranging from a minimum spacing distance to about 0.3 microns (μm).

Gate-all-around integrated circuit structures including varactors are described. For example, an integrated circuit structure includes a varactor structure on a semiconductor substrate. The varactor structure includes a plurality of discrete vertical arrangements of horizontal nanowires. A plurality of gate stacks is over and surrounding corresponding ones of the plurality of discrete vertical arrangements of horizontal nanowires. The integrated circuit structure also includes a tap structure adjacent to the varactor structure on the semiconductor substrate. The tap structure includes a plurality of merged vertical arrangements of horizontal nanowires. A plurality of semiconductor structures is over and surrounding corresponding ones of the plurality of merged vertical arrangements of horizontal nanowires.