An approach for heat dissipation in integrated circuit devices is provided. A method includes forming an isolation layer on an electrically conductive feature of an integrated circuit device. The method also includes forming an electrically conductive layer on the isolation layer. The method additionally includes forming a plurality of nanowire structures on a surface of the electrically conductive layer.

An integrated circuit contains three thin film resistors over a dielectric layer. The first resistor body includes only a bottom thin film layer and the first resistor heads include the bottom thin film layer, a middle thin film layer and a top thin film layer. The second resistor body and heads include all three thin film layers. The third resistor body does not include the middle thin film layer. The three resistors are formed using two etch masks.

An LED package structure includes a substrate, a circuit layer and an insulating layer both disposed on the substrate, a light-emitting unit, and a reflective housing integrally formed with the insulating layer. The light-emitting unit includes an LED chip and a fluorescent body encapsulating the LED chip. The light-emitting unit is mounted on the insulating layer and the circuit layer. The fluorescent body of the light emitting unit is spaced apart from the circuit layer with a gap in a range of 310 m. The reflective housing is formed on the insulating layer and the circuit layer and is further filled within the gap. A top plane of the reflective housing arranged away from the substrate is lower than or equal to that of the light-emitting unit, and a distance between the two top planes is in a range of 030 m.

A method for producing a polysilicon resistor device may include: forming a polysilicon layer; implanting first dopant atoms into at least a portion of the polysilicon layer, wherein the first dopant atoms include deep energy level donors; implanting second dopant atoms into said at least a portion of said polysilicon layer; and annealing said at least a portion of said polysilicon layer.

The disclosed technology relates generally to a semiconductor device package comprising a metal-insulator-metal capacitor (MIMCAP). In one aspect, the MIMCAP comprises portions of a first and second metallization layers in a stack of metallization layers, e.g., copper metallization layers formed by single damascene processes. The MIMCAP comprises a bottom plate formed in the first metallization layer, a first conductive layer on and in electrical contact with the bottom plate, a dielectric layer on and in contact with the first conductive layer, a second conductive layer on and in contact with the dielectric layer, and a top plate formed in the second metallization layer, on and in electrical contact with the second metal plate. The electrical contacts to the bottom and top plates of the MIMCAP formed in the first and second metallization layer are thereby established without forming separate vias between the plates and the metallization layers. In addition, the first conductive layer of the MIMCAP may extend beyond the surface of the dielectric and the second layer for forming other structures.

Approaches for silicon photonics integration are provided. A method includes: forming at least one encapsulating layer over and around a photodetector; thermally crystallizing the photodetector material after the forming the at least one encapsulating layer; and after the thermally crystallizing the photodetector material, forming a conformal sealing layer on the at least one encapsulating layer and over at least one device. The conformal sealing layer is configured to seal a crack in the at least one encapsulating layer. The photodetector and the at least one device are on a same substrate. The at least one device includes a complementary metal oxide semiconductor device or a passive photonics device.

Electrical fuse (eFuse) and resistor structures and methods of manufacture are provided. The method includes forming metal gates having a capping material on a top surface thereof. The method further includes protecting the metal gates and the capping material during an etching process which forms a recess in a dielectric material. The method further includes forming an insulator material and metal material within the recess. The method further includes forming a contact in direct electrical contact with the metal material.

A semiconductor device includes a substrate and a source metal formed on the substrate. A gate pad is formed on the substrate adjacent to the source metal. A gate metal is formed on the substrate and surrounds the gate pad and the source metal. A first diode is formed between the gate metal and the source metal.

An integrated circuit containing CMOS gates and a counterdoped polysilicon gate material resistor which has a body region that is implanted concurrently with the NSD layers of the NMOS transistors of the CMOS gates and concurrently with the PSD layers of the PMOS transistors of the CMOS gates, and has a resistor silicide block layer over the body region which is formed of separate material from the sidewall spacers on the CMOS gates. A process of forming an integrated circuit containing CMOS gates and a counterdoped polysilicon gate material resistor which implants the body region of the resistor concurrently with the NSD layers of the NMOS transistors of the CMOS gates and concurrently with the PSD layers of the PMOS transistors of the CMOS gates, and forms a resistor silicide block layer over the body region of separate material from the sidewall spacers on the CMOS gates.

A method of forming a polysilicon resistor in replacement metal gate (RMG) processing of finFET devices includes forming a plurality of semiconductor fins over a buried oxide layer of a silicon-on-insulator substrate; forming a trench in the buried oxide layer; forming a polysilicon layer over the semiconductor fins and in the trench, the polysilicon layer having a depression corresponding to a location of the trench; forming an insulating layer over the polysilicon layer, and performing a planarizing operation to remove the insulating layer except for a portion of the insulating layer formed in the depression, thereby defining a protective island; patterning the polysilicon layer to define both a dummy gate structure over the fins and the polysilicon resistor; and etching the polysilicon layer to remove the dummy gate structure, wherein the protective island prevents the polysilicon resistor from being removed.