Provided is a method of cyclically depositing a thin film including: performing an oxide depositing operation of repeatedly performing a deposition operation, a first purge operation, a reaction operation, and a second purge operation, wherein the deposition operation deposits silicon on a target by injecting a silicon precursor into a chamber into which the target is loaded, the first purge operation removes a non-reacted silicon precursor and a reacted byproduct from inside the chamber, the reaction operation supplies a first reaction source including oxygen into the chamber to form the deposited silicon as an oxide including silicon, and the second purge operation removes a non-reacted first reaction source and a reacted byproduct from the inside of the chamber; and performing a plasma processing operation of supplying plasma made of a second reaction source including nitrogen to the inside of the chamber to process the oxide including the silicon.

Semiconductor structures and methods for forming the same are provided. The method includes forming a dummy gate structure over a substrate and forming a sealing layer surrounding the dummy gate structure. The method includes forming a spacer covering the sealing layer and removing the dummy gate structure to form a trench. The method further includes forming an interfacial layer and a gate dielectric layer. The method further includes forming a capping layer over the gate dielectric layer and partially oxidizing the capping layer to form a capping oxide layer. The method further includes forming a work function metal layer over the capping oxide layer and forming a gate electrode layer over the work function metal layer. In addition, a bottom surface of the capping oxide layer is higher than a bottom surface of the spacer.

A semiconductor device has a substrate with a semiconductor material. The semiconductor device includes a field effect transistor in and on the semiconductor material. The field effect transistor has a gate dielectric layer over the semiconductor material of the semiconductor device, and a gate over the gate dielectric layer. The gate dielectric layer includes a layer of nitrogen-rich silicon nitride immediately over the region for the channel, and under the gate.

A semiconductor structure includes a semiconductor substrate, n-type and p-type FinFETs on the substrate, each of the n-type and the p-type FinFETs include a channel region and a gate structure surrounding the channel region, each gate structure having a phase-changed high-k gate dielectric layer lining a gate trench thereof, the gate trench defined by a pair of spacers. The semiconductor structure further includes a conformal dielectric capping layer over each phase-changed high-k gate dielectric layer, the conformal dielectric capping layer having a higher dielectric constant than the phase-changed high-k gate dielectric layer. Further included on the n-type FinFETs is a multi-layer replacement gate stack of n-type work function material over the phase-changed high-k gate dielectric layer. A method of fabricating the semiconductor structure is also provided.

Contact over active gate (COAG) structures with etch stop layers, and methods of fabricating contact over active gate (COAG) structures using etch stop layers, are described. In an example, an integrated circuit structure includes a plurality of gate structures above substrate, each of the gate structures including a gate insulating layer thereon. A plurality of conductive trench contact structures is alternating with the plurality of gate structures, each of the conductive trench contact structures including a trench insulating layer thereon. A first dielectric etch stop layer is directly on and continuous over the trench insulating layers and the gate insulating layers. A second dielectric etch stop layer is directly on and continuous over the first dielectric etch stop layer, the second dielectric etch stop layer distinct from the first dielectric etch stop layer. An interlayer dielectric material is on the second dielectric etch stop layer.

Embodiments of the present disclosure generally relate to methods for forming a high-k gate dielectric in a transistor. The high-k gate dielectric may be formed by introducing a fluorine containing gas into a processing chamber during the deposition of the high-k gate dielectric in the processing chamber. In one embodiment, the high-k gate dielectric is formed by an ALD process in a processing chamber, and a fluorine containing gas is introduced into the processing chamber during one or more stages of the ALD process. Fluorine ions, molecules or radicals from the fluorine containing gas (may be activated by a plasma) can fill the oxygen vacancies in the high-k dielectric.

A device includes a first Group III-Nitride (III-N) material, a gate electrode above the III-N material, and the gate electrode. The device further includes a tiered field plate, suitable for increasing gate breakdown voltage with minimal parasitics. In the tiered structure, a first plate is on the gate electrode, the first plate having a second sidewall laterally beyond a sidewall of the gate, and above the III-N material by a first distance. A second plate on the first plate has a third sidewall laterally beyond the second sidewall and above the III-N material by a second distance, greater than the first. A source structure and a drain structure are on opposite sides of the gate electrode, where the source and drain structures each include a second III-N material.

Gate structures for semiconductor devices include a silicon nitride layer, an electron beam evaporated tantalum nitride layer disposed on the silicon nitride layer, a first electron beam evaporated titanium layer disposed on the tantalum nitride layer, an electron beam evaporated gold layer deposited on the first titanium layer, and a second electron beam evaporated titanium layer deposited on the gold layer.

A method of manufacturing a high electron mobility transistor in a furnace, the method including steps of: forming a first SiN film on a surface of a semiconductor stack consisting of a nitride semiconductor and including a barrier layer by a low pressure chemical vapor deposition method at a first furnace temperature of 700° C. or more and 900° C. or less; forming an interface oxide layer on the first SiN film by moisture and oxygen in the furnace at a second furnace temperature of 700° C. or more and 900° C. or less and a furnace pressure to 1 Pa or lower; and forming a second SiN film on the interface oxide layer by the low pressure chemical vapor deposition method at a third furnace temperature of 700° C. or more and 900° C. or less.

A dual gate CMOS structure including a semiconductor substrate; a first channel structure including a first semiconductor material and a second channel structure including a second semiconductor material on the substrate. The first semiconductor material including Si.sub.xGe.sub.1−x where x=0 to 1 and the second semiconductor material including a group III-V compound material. A first gate stack on the first channel structure includes: a first native oxide layer as an interface control layer, the first native oxide layer comprising an oxide of the first semiconductor material; a first high-k dielectric layer; a first metal gate layer. A second gate stack on the second channel structure includes a second high-k dielectric layer; a second metal gate layer. The interface between the second channel structure and the second high-k dielectric layer is free of any native oxides of the second semiconductor material.