An integrated circuit structure includes a substrate, a transistor, a first dielectric layer, a metal contact, a first low-k dielectric layer, a second dielectric layer, and a first metal feature. The transistor is over the substrate. The first dielectric layer is over the transistor. The metal contact is in the first dielectric layer and electrically connected to the transistor. The first low-k dielectric layer is over the first dielectric layer. The second dielectric layer is over the first low-k dielectric layer and has a dielectric constant higher than a dielectric constant of the first low-k dielectric layer. The first metal feature extends through both second dielectric layer and the first low-k dielectric layer to the metal contact.

A transistor includes a plurality of gate fingers that extend in a first direction and are spaced apart from each other in a second direction, each of the gate fingers comprising at least spaced-apart and generally collinear first and second gate finger segments that are electrically connected to each other. The first gate finger segments are separated from the second gate finger segments in the first direction by a gap region that extends in the second direction. A resistor is disposed in the gap region.

Gallium nitride (GaN) transistors with source and drain field plates are described. In an example, a transistor includes a gallium nitride (GaN) layer above a substrate, a gate structure over the GaN layer, a source region on a first side of the gate structure, a drain region on a second side of the gate structure, the second side opposite the first side, a source field plate above the source region, and a drain field plate above the drain region.

A vertically stacked set of an n-type vertical transport field effect transistor (n-type VT FET) and a p-type vertical transport field effect transistor (p-type VT FET) is provided. The vertically stacked set of the n-type VT FET and the p-type VT FET includes a first bottom source/drain layer on a substrate, that has a first conductivity type, a lower channel pillar on the first bottom source/drain layer, and a first top source/drain on the lower channel pillar, that has the first conductivity type. The vertically stacked set of the n-type VT FET and the p-type VT FET further includes a second bottom source/drain on the first top source/drain, that has a second conductivity type different from the first conductivity type, an upper channel pillar on the second bottom source/drain, and a second top source/drain on the upper channel pillar, that has the second conductivity type.

A transistor including at least one two-dimensional (2D) channel is disclosed. A transistor according to some example embodiments includes first to third electrodes separated from each other, and a channel layer that is in contact with the first and second electrodes, parallel to the third electrode, and includes at least one 2D channel. The at least one 2D channel includes at least two regions having different doping concentrations. A transistor according to some example embodiments includes: first to third electrodes separated from each other; a 2D channel layer that is in contact with the first and second electrodes and parallel to the third electrode; a first doping layer disposed under the 2D channel layer corresponding to the first electrode; and a second doping layer disposed under the 2D channel layer corresponding to the second electrode, wherein the first and second doping layers contact the 2D channel layer.

A semiconductor device may include a plurality of active patterns and a plurality of gate structure on a substrate, a first insulating interlayer covering the active patterns and the gate structures, a plurality of first contact plugs extending through the first insulating interlayer, a plurality of second contact plugs extending through the first insulating interlayer, and a first connecting pattern directly contacting a sidewall of at least one contact plug selected from the first and second contact plugs. Each of gate structures may include a gate insulation layer, a gate electrode and a capping pattern. Each of first contact plugs may contact the active patterns adjacent to the gate structure. Each of the second contact plugs may contact the gate electrode in the gate structures. An upper surface of the first connecting pattern may be substantially coplanar with upper surfaces of the first and second contact plugs.

A split gate carrier stored trench bipolar transistor (CSTBT) with current clamping PMOS include a P-type buried layer and a split gate electrode with equal potential to an emitter metal on the basis of the traditional CSTBT, which effectively eliminates the influence of an N-type carrier stored layer on breakdown characteristics of the device through the charge compensation effect, and helps to improve the trade-off relationship between the on-state voltage drop and the turn-off loss. Moreover, the introduction of a parasitic PMOS structure can reduce the saturation current and improve short-circuit safe operating area of the device, reduce the Miller capacitance, and improve the switching speed of the device and reduce the switching loss of the device. In addition, the split gate CSTBT integrating the split gate electrode and gate electrode in the same trench can shorten the distance between PMOS and NMOS channels.

The semiconductor device includes a first source/drain layer, a dielectric layer, a channel, a gate electrode, a first gate dielectric layer, a seed layer, a conductive layer, and a second source/drain layer. The dielectric layer is disposed on the first source/drain layer, in which the dielectric layer has a hole penetrating the dielectric layer. The channel is disposed in the hole and extends substantially perpendicular to an upper surface of the first source/drain layer. The gate electrode surrounds the channel. The first gate dielectric layer is disposed between the gate electrode and the channel. The seed layer is disposed between the gate electrode and the dielectric layer and on an upper surface of the dielectric layer, in which the seed layer covers a portion of a sidewall of the hole.

An integrated circuit includes a first nanosheet transistor and a second nanosheet transistor on a substrate. The first and second nanosheet each include gate electrodes. A gate isolation structure extends from a backside of the substrate between the gate electrodes. The gate isolation structure physically and electrically isolates the first and second gate electrodes from each other.

An interconnect fabrication method is disclosed herein that utilizes a disposable etch stop hard mask over a gate structure during source/drain contact formation and replaces the disposable etch stop hard mask with a dielectric feature (in some embodiments, dielectric layers having a lower dielectric constant than a dielectric constant of dielectric layers of the disposable etch stop hard mask) before gate contact formation. An exemplary device includes a contact etch stop layer (CESL) having a first sidewall CESL portion and a second sidewall CESL portion separated by a spacing and a dielectric feature disposed over a gate structure, where the dielectric feature and the gate structure fill the spacing between the first sidewall CESL portion and the second sidewall CESL portion. The dielectric feature includes a bulk dielectric over a dielectric liner. The dielectric liner separates the bulk dielectric from the gate structure and the CESL.