A method includes: forming first and second trenches in a semiconductor body; forming a first material layer on the semiconductor body in the first and second trenches such that a first residual trench remains in the first trench and a second residual trench remains in the second trench; removing the first material from the second trench; and forming a second material layer on the first material layer in the first residual trench and on the semiconductor body in the second trench. The first material layer includes dopants of a first doping type and the second material layer includes dopants of a second doping type. The method further includes diffusing dopants from the first material layer in the first trench into the semiconductor body to form a first doped region, and from the second material layer in the second trench into the semiconductor body to form a second doped region.

A fin field-effect transistor (fin-FET) includes a substrate having a plurality of discrete fin structures thereon; a chemical oxide layer on at least a sidewall of a fin structure; a doped layer containing doping ions on the chemical oxide layer; and a doped region in the fin structure containing doping ions diffused from the doping ions in the doped layer.

Hydrogen annealing for heating a semiconductor wafer on which a thin film containing a dopant is deposited to an annealing temperature under an atmosphere containing hydrogen is performed. A native oxide film is inevitably formed between the thin film containing the dopant and the semiconductor wafer, however, by performing hydrogen annealing, the dopant atoms diffuse relatively easily in the native oxide film and accumulate at the interface between the front surface of the semiconductor wafer and the native oxide film. Subsequently, the semiconductor wafer is preheated to a preheating temperature under a nitrogen atmosphere, and then, flash heating treatment in which the front surface of the semiconductor wafer is heated to a peak temperature for less than one second is performed. The dopant atoms are diffused and activated in a shallow manner from the front surface of the semiconductor wafer, thus, the low-resistance and extremely shallow junction is obtained.

An impurity source film is formed along a portion of a non-planar semiconductor fin structure. The impurity source film may serve as source of an impurity that becomes electrically active subsequent to diffusing from the source film into the semiconductor fin. In one embodiment, an impurity source film is disposed adjacent to a sidewall surface of a portion of a sub-fin region disposed between an active region of the fin and the substrate and is more proximate to the substrate than to the active area.

The present disclosure provides a method for fabricating a fin field-effect transistor (fin-FET), including: providing a substrate having a plurality of discrete fin structures thereon; forming a chemical oxide layer on at least a sidewall of a fin structure; forming a doped layer containing doping ions on the chemical oxide layer; and annealing the doped layer such that the doping ions diffuse into the fin structure to form a doped region.

A fin field effect transistor includes a Si fin including a central portion between end portions of the fin, and a SiGe channel region disposed on the central portion of the fin. The SiGe channel region includes a facet free SiGe region having Ge atoms diffused into the Si fin and includes a same shape as the Si fin outside the central portion.

A method for fabricating a semiconductor structure is provided in the present invention. The method includes the steps of forming a plurality of fins in a first region, a second region and a dummy region, forming a first solid-state dopant source layer and a first insulating buffer layer in the first region, forming a second solid-state dopant source layer and a second insulating buffer layer in the second region and the dummy region, and performing an etch process to cut the fin in the dummy region.

The present invention provides stacked VFET devices. In one aspect, a method of forming a stacked VFET device includes: patterning a fin(s) in a wafer having a vertical fin channel of a VFET1 separated from a vertical fin channel of a VFET2 by an insulator; forming a bottom source and drain of the VFET1 below the vertical fin channel of the VFET1; forming a gate of the VFET1 alongside the vertical fin channel of the VFET1; forming a gate of the VFET2 alongside the vertical fin channel of the VFET2; forming a top source and drain of the VFET1 above the vertical fin channel of the VFET1; forming a bottom source and drain of the VFET2 below the vertical fin channel of the VFET2; and forming a top source and drain of the VFET2 above the vertical fin channel of the VFET2. A stacked VFET device is also provided.

One illustrative method disclosed includes, among other things, forming a gate structure around a fin and above a layer of insulating material, forming a gate spacer adjacent the gate structure and a fin spacer positioned adjacent the fin above the insulating material, the fin spacer leaving an upper surface of the fin exposed, and performing at least one etching process to remove at least a portion of the fin positioned between the fin spacer, the fin having a recessed upper surface that at least partially defines a fin recess positioned between the fin spacer. In this example, the method further includes forming an epi semiconductor material on the fin recess and removing the fin spacer from adjacent the epi semiconductor material while leaving a portion of the gate spacer in position adjacent the gate structure.

A reverse-blocking IGBT (insulated gate bipolar transistor) includes a plurality of IGBT cells disposed in a device region of a semiconductor substrate, a reverse-blocking edge termination structure disposed in a periphery region of the semiconductor substrate which surrounds the device region, one or more trenches formed in the periphery region between the reverse-blocking edge termination structure and an edge face of the semiconductor substrate, a p-type dopant source at least partly filling the one or more trenches, and a continuous p-type doped region disposed in the periphery region and formed from p-type dopants out-diffused from the p-type dopant source. The continuous p-type doped region extends from a top surface of the semiconductor substrate to a bottom surface of the semiconductor substrate.