A method for forming a semiconductor structure includes the following steps. A semiconductor device is formed over a substrate. A trench is formed in the semiconductor device. The trench is filled with a gap-fill material using a deposition process, wherein a precursor used in the deposition process includes azidosilane, di-azidosilane or halide azidosilane.

A device structure includes a substrate, a fin structure disposed on the substrate and elongated in an X direction, a gate structure formed on the fin structure and elongated in a Y direction transverse to the X direction to terminate at two opposite ends, at least one dielectric portion connected to at least one of the two opposite ends of the gate structure, and having two sides that are opposite to each other in the X direction, and a pair of gate spacers which are spaced apart from each other in the X direction and are respectively disposed on two lateral sides of the gate structure, and which are elongated in the Y direction to cover the two sides of the dielectric portion, respectively. A method for manufacturing the device structure is also disclosed.

Semiconductor structures and methods are provided. An exemplary method according to the present disclosure includes forming a first and a second fin-shaped active region over a substrate, the first and second fin-shaped active regions extending lengthwise along a first direction, forming a gate structure over channel regions of the first and second fin-shaped active regions, the gate structure extending lengthwise along a second direction substantially perpendicular to the first direction, forming a trench to separate the gate structure into two segments, the trench extending lengthwise along the first direction and being disposed between the first and second fin-shaped active regions, performing an etching process to enlarge an upper portion of the trench, and forming a gate isolation structure in the trench, and, in a cross-sectional view cut through both the first and second fin-shaped active regions and the gate structure, the gate isolation structure is a T-shape structure.

A transistor and a manufacturing method. The transistor includes a semiconductor base substrate, an active structure, a dielectric structure, and a gate stack structure. The active structure is formed on the semiconductor base substrate. The active structure includes a source region, a drain region, and a channel region located between the source region and the drain region. The channel region includes at least two nanostructures stacked in a thickness direction of the semiconductor base substrate. In the channel region, a bottom nanostructure has a greater width than other nanostructures. The dielectric structure is formed between the semiconductor base substrate and the active structure. The dielectric structure is in contact with the bottom nanostructure. The gate stack structure is formed on a surface of the bottom nanostructure not in contact with the dielectric structure, and the gate stack surrounds a periphery of the other nanostructures.

To improve field-effect mobility and reliability in a transistor including an oxide semiconductor film. A semiconductor device includes a transistor including an oxide semiconductor film. The transistor includes a region where the maximum value of field-effect mobility of the transistor at a gate voltage of higher than 0 V and lower than or equal to 10 V is larger than or equal to 40 and smaller than 150; a region where the threshold voltage is higher than or equal to minus 1 V and lower than or equal to 1 V; and a region where the S value is smaller than 0.3 V/decade.

An integrated circuit includes a first nanostructure transistor having a first gate electrode and a second nanostructure transistor having a second gate electrode. A dielectric isolation structure is between the first and second gate electrodes. A gate connection metal is on a portion of the top surface of the first gate electrode and on a portion of a top surface of the second gate electrode. The gate connection metal is patterned to expose other portions of the top surfaces of the first and second gate electrodes adjacent to the dielectric isolation structure. A conductive via contacts the exposed portion of the top surface of the second gate electrode.

An object is to obtain a semiconductor device having a high sensitivity in detecting signals and a wide dynamic range, using a thin film transistor in which an oxide semiconductor layer is used. An analog circuit is formed with the use of a thin film transistor including an oxide semiconductor which has a function as a channel formation layer, has a hydrogen concentration of 510.sup.19 atoms/cm.sup.3 or lower, and substantially functions as an insulator in the state where no electric field is generated. Thus, a semiconductor device having a high sensitivity in detecting signals and a wide dynamic range can be obtained.

Improved methods for forming gate isolation structures between portions of gate electrodes and semiconductor devices formed by the same are disclosed. In an embodiment, a method includes forming a channel structure over a substrate; forming a first isolation structure extending in a direction parallel to the channel structure; forming a dummy gate structure over the channel structure and the first isolation structure; depositing a hard mask layer over the dummy gate structure; etching the hard mask layer to form a first opening through the hard mask layer over the first isolation structure; conformally depositing a first dielectric layer over the hard mask layer, in the first opening, and over the dummy gate structure; etching the first dielectric layer to extend the first opening and expose the dummy gate structure; and etching the dummy gate structure to extend the first opening and expose the first isolation structure.

A method for manufacturing a semiconductor device including an upper-channel implant transistor is provided. The method includes forming one or more fins extending in a first direction over a substrate. The one or more fins include a first region along the first direction and second regions on both sides of the first region along the first direction. A dopant is shallowly implanted in an upper portion of the first region of the fins but not in the second regions and not in a lower portion of the first region of the fins. A gate structure extending in a second direction perpendicular to the first direction is formed overlying the first region of the fins, and source/drains are formed overlying the second regions of the fins, thereby forming an upper-channel implant transistor.

A method includes forming a semiconductive channel layer on a substrate. A dummy gate is formed on the semiconductive channel layer. Gate spacers are formed on opposite sides of the dummy gate. The dummy gate is removed to form a gate trench between the gate spacers, resulting in the semiconductive channel layer exposed in the gate trench. A semiconductive protection layer is deposited in the gate trench and on the exposed semiconductive channel layer. A top portion of the semiconductive protection layer is oxidized to form an oxidation layer over a remaining portion of the semiconductive protection layer. The oxidation layer is annealed after the top portion of the semiconductive protection layer is oxidized. A gate structure is formed over the semiconductive protection layer and in the gate trench after the oxidation layer is annealed.