The reliability of a semiconductor device is improved. A first insulating film and a protective film are formed on a semiconductor substrate. The first insulating film and the protective film of a first region are selectively removed, and an insulating film is formed on the exposed semiconductor substrate. In a state where the first insulating film in a second region, a third region, and a fourth region is covered with the protective film, the semiconductor substrate is heat-treated in an atmosphere containing nitrogen, thereby introducing nitrogen to the interface between the semiconductor substrate and the second insulating film in the first region. In other words, a nitrogen introduction point is formed on the interface between the semiconductor substrate and the second insulating film. In this configuration, the protective film acts as an anti-nitriding film.

A photomask includes a reticle substrate, a main pattern disposed on the reticle substrate and defining a photoresist pattern realized on a semiconductor substrate, and anti-reflection patterns adjacent to the main pattern. A distance between a pair of the anti-reflection patterns adjacent to each other is a first length, and a width of at least one of the pair of anti-reflection patterns is a second length. A sum of the first length and the second length is equal to or smaller than a minimum pitch defined by resolution of an exposure process. A distance between the main pattern and the anti-reflection pattern nearest to the main pattern is equal to or smaller than the first length.

An electrical contact structure (an MIS contact) includes one or more conductors (M-Layer), a semiconductor (S-Layer), and an interfacial dielectric layer (I-Layer) of less than 4 nm thickness disposed between and in contact with both the M-Layer and the S-Layer. The I-Layer is an oxide of a metal or a semiconductor. The conductor of the M-Layer that is adjacent to and in direct contact with the I-Layer is a metal oxide that is electrically conductive, chemically stable and unreactive at its interface with the I-Layer at temperatures up to 450 C. The electrical contact structure has a specific contact resistivity of less than or equal to approximately 10.sup.5-10.sup.7 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 210.sup.19 cm.sup.3 and less than approximately 10.sup.8 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 10.sup.20 cm.sup.3.

A manufacturing method of an integrated circuit includes following steps. A dummy gate with a first mask structure formed thereon and a semiconductor gate with a second mask structure formed thereon are formed on a substrate. A top surface of the semiconductor gate is lower than a top surface of the dummy gate. A first removing process is performed to remove the first mask structure and a part of the second mask structure. A dielectric layer is formed covering the dummy gate, the semiconductor gate, and the second mask structure. A second removing process is performed to remove the dielectric layer above the dummy gate. The dummy gate is removed for forming a trench. A metal gate structure is formed in the trench. The semiconductor gate is covered by the second mask structure during the second removing process and the step of removing the dummy gate.

The structures and methods disclosed herein include changing composition of a metal alloy layer in an epitaxial electrode material to achieve tunable work functions for the electrode. In one example, the tunable work function is achieved using a layered structure, in which a crystalline rare earth oxide (REO) layer is epitaxially over a substrate or semiconductor, and a metal layer is over the crystalline REO layer. A semiconductor layer is thus in turn epitaxially grown over the metal layer, with a metal alloy layer over the semiconductor layer such that the ratio of constituents in the metal alloy is used to tune the work function of the metal layer.

Embodiments are directed to a method of forming a stacked nanosheet and resulting structures having equal thickness work function metal layers. A nanosheet stack is formed on a substrate. The nanosheet stack includes a first sacrificial layer formed on a first nanosheet. A hard mask is formed on the first sacrificial layer and the first sacrificial layer is removed to form a cavity between the hard mask and the first nanosheet. A work function layer is formed to fill the cavity between the hard mask and the first nanosheet.

Embodiments are directed to a method of forming a stacked nanosheet and resulting structures having equal thickness work function metal layers. A nanosheet stack is formed on a substrate. The nanosheet stack includes a first sacrificial layer formed on a first nanosheet. A hard mask is formed on the first sacrificial layer and the first sacrificial layer is removed to form a cavity between the hard mask and the first nanosheet. A work function layer is formed to fill the cavity between the hard mask and the first nanosheet.

An integrated circuit device, and a method of forming, including a semiconductor substrate, isolation regions extending into the semiconductor substrate, a semiconductor strip, and a semiconductor fin overlapping and joined to the semiconductor strip is provided. A first dielectric layer and a second dielectric layer are disposed on opposite sidewalls of the semiconductor strip. The integrated circuit device further includes a first conductive liner and a second conductive liner, wherein the semiconductor strip, the first dielectric layer, and the second dielectric layer are between the first conductive liner and the second conductive line. The first conductive liner and the second conductive liner are between, and in contact with, sidewalls of a first portion and a second portion of the isolation regions.

Semiconductor devices and methods of forming the same are provided. A method according to the present disclosure includes providing a workpiece including a frontside and a backside. The workpiece includes a substrate, a first plurality of channel members over a first portion of the substrate, a second plurality of channel members over a second portion of the substrate, an isolation feature sandwiched between the first and second portions of the substrate. The method also includes forming a joint gate structure to wrap around each of the first and second pluralities of channel members, forming a pilot opening in the isolation feature, extending the pilot opening through the join gate structure to form a gate cut opening that separates the joint gate structure into a first gate structure and a second gate structure, and depositing a dielectric material into the gate cut opening to form a gate cut feature.

A semiconductor device is provided, which includes a substrate, a shallow trench isolation (STI), a gate dielectric structure, a capping structure and a gate structure. The STI is in the substrate and defines an active area of the substrate. The gate dielectric structure is on the active area. The capping structure is adjacent to the gate dielectric structure and at edges of the active area. The gate structure is on the gate dielectric structure and the capping structure. An equivalent oxide thickness of the capping structure is substantially greater than an equivalent oxide thickness of the gate dielectric structure.