A method of forming an integrated circuit with a metal-insulator-poly (MIP) capacitor formed in a high-k metal gate (HKMG) process and the resulting device are provided. Embodiments include a device including a metal gate; a high-k dielectric layer formed around side walls of the metal gate, and a dummy polysilicon gate adjacent to at least one portion of the high-k dielectric layer. The device also includes a capacitor including the HK layer as an insulator, wherein the insulator is between a dummy as one electrode and the metal gate as another electrode.

A device includes a substrate, a buffer layer, a nanowire, a gate structure, and a remnant of a sacrificial layer. The buffer layer is above the substrate. The nanowire is above the buffer layer and includes a pair of source/drain regions and a channel region between the source/drain regions. The gate structure surrounds the channel region. The remnant of the sacrificial layer is between the buffer layer and the nanowire and includes a group III-V semiconductor material.

A method includes depositing a first work-function layer and a second work-function layer in a first device region and a second device region, respectively, and depositing a first fluorine-blocking layer and a second fluorine-blocking layer in the first device region and the second device region, respectively. The first fluorine-blocking layer is over the first work-function layer, and the second fluorine-blocking layer is over the second work-function layer. The method further includes removing the second fluorine-blocking layer, and forming a first metal-filling layer over the first fluorine-blocking layer, and a second metal-filling layer over the second work-function layer.

A method includes providing a starting semiconductor structure, the starting semiconductor structure including a semiconductor substrate with active region(s) separated by isolation regions, the active region(s) including source/drain regions of epitaxial semiconductor material, dummy gate structures adjacent each source/drain region, the dummy gate structures including dummy gate electrodes with spacers adjacent opposite sidewalls thereof and gate caps thereover, and openings between the dummy gate structures. The method further includes filling the openings with a dielectric material, recessing the dielectric material, resulting in a filled and recessed structure, and forming a hard mask liner layer over the filled and recessed structure to protect against loss of the recessed dielectric material during subsequent removal of unwanted dummy gate electrodes. A resulting semiconductor structure formed by the method is also provided.

A method of manufacturing a semiconductor device includes providing a semiconductor structure including a substrate, a semiconductor fin on the substrate, and a dummy gate structure on the semiconductor fin. The dummy gate structure includes a dummy gate dielectric layer on the semiconductor fin and a dummy gate on the dummy gate dielectric layer. The method also includes forming an interlayer dielectric layer on the semiconductor substrate, planarizing the interlayer dielectric layer to expose an upper surface of the dummy gate, and performing a first doping implant into the semiconductor fin through the dummy gate to form an anti-puncture region in the semiconductor fin. The anti-puncture region has an upper surface lower than an upper surface of a trench isolation portion surrounding the semiconductor fin to prevent a punch through of a source and drain, reducing a current leakage and parasitic capacitance of the semiconductor device.

Structures that include bipolar junction transistors and methods of forming such structures. The structure comprises a semiconductor layer, a substrate, and a dielectric layer disposed between the semiconductor layer and the substrate. The structure further comprises a first bipolar junction transistor including a first collector in the substrate, a first emitter, and a first base layer. The first base layer extends through the dielectric layer from the first emitter to the first collector. The structure further comprises a second bipolar junction transistor including a second collector in the substrate, a second emitter, and a second base layer. The second base layer extends through the dielectric layer from the second emitter to the second collector. The second base layer is connected to the first base layer by a section of the semiconductor layer to define a base line.

A semiconductor device includes a first and a second nitride-based semiconductor layers and a gate structure. The gate structure includes an outer spacer, an inner spacer and a gate electrode. The outer spacer has at least two opposite inner sidewalls to define a gate trench. The inner spacer is within the gate trench. The gate electrode disposed in the gate trench and covered by the inner spacer, wherein the inner spacer and the gate electrode extend downward to collaboratively form a bottom portion of the gate structure with a first width greater than a second width of a bottom surface of the gate electrode.

A method of fabricating a semiconductor device includes forming a fin in a substrate and depositing a spacer material on the fin. The method includes recessing the spacer material so that a surface of the fin is exposed. The method includes removing a portion of the fin within lateral sidewalls of the spacer material to form a recess, leaving a portion of the fin on the lateral sidewalls. The method further includes depositing a semiconductor material within the recess.

A method of fabricating a semiconductor device includes forming a fin in a substrate and depositing a spacer material on the fin. The method includes recessing the spacer material so that a surface of the fin is exposed. The method includes removing a portion of the fin within lateral sidewalls of the spacer material to form a recess, leaving a portion of the fin on the lateral sidewalls. The method further includes depositing a semiconductor material within the recess.

A device includes a substrate, a buffer layer, a nanowire, a gate structure, and a remnant of a sacrificial layer. The buffer layer is above the substrate. The nanowire is above the buffer layer and includes a pair of source/drain regions and a channel region between the source/drain regions. The gate structure surrounds the channel region. The remnant of the sacrificial layer is between the buffer layer and the nanowire and includes a group III-V semiconductor material.