Abstract: A silicon on insulator device has a silicon layer (10) over a buried insulating layer (12). A nickel layer is deposited over a gate (16), on sidewall spacers (22) on the sides of the gate (16), and in a cavity on both sides of the gate (16) in the silicon layer (10). A doped amorphous silicon layer fills the cavity. Annealing then takes place which forms polysilicon (40) over the sidewall spacers (22) and gate (16), but where the nickel is adjacent to single crystal silicon (10) a layer of NiSi (44) migrates to the surface leaving doped single crystal silicon (42) behind, forming in one step a source, drain, and source and drain contacts.

Abstract: The invention relates to a method of manufacturing a semiconductor device (1.

Abstract: Methods of forming semiconductor devices with a layered structure of thin and well defined layer of activated dopants, are disclosed. In a preferred method, a region in a semiconductor substrate is amorphized, after which the region is implanted with a first dopant at a first doping concentration. Then a solid phase epitaxy regrowth step is performed on a thin layer of desired thickness of the amorphized region, in order to activate the first dopant only in this thin layer. Subsequently, a second dopant is implanted in the remaining amorphous region at a second doping concentration. Subsequent annealing of the substrate activates the second dopant only in said remaining region, so a very abrupt transition between dopant characteristics of the thin layer with first dopant and the region with the second dopant is obtained.

Abstract: A transistor device is formed of a continuous linear nanostructure having a source region, a drain region and a channel region between the source and drain regions. The source (20) and drain (26) regions are formed of nanowire ania the channel region (24) is in the form of a nanotube. An insulated gate (32) is provided adjacent to the channel region (24) for controlling conduction i ni the channel region between the source and drain regions.

Abstract: The present invention discloses a method of forming a double gate field effect transistor device, and such a device formed with the method. One starts with a semiconductor-on-insulator substrate, and forms a first gate, source, drain and extensions, and prepares the second gate. Then the substrate is bonded to a second carrier, exposing a second side of the semiconductor layer. Next, an annealing step is performed as a diffusionless annealing, which has the advantage that the semiconductor layer not only has a substantially even thickness, but also has a substantially flat surface. This ensures the best possible annealing action of said annealing step. Very sharp abruptness of the extensions is achieved, with very high activation of the dopants.

Abstract: Methods of providing a semiconductor device with a control electrode structure having a controlled overlap between control electrode and first and second main electrode extensions without many spacers are disclosed. A preferred method provides a step of etching back an insulating layer performed after amorphizing and implanting the main electrode extensions. Preferably, the step that amorphizes the extensions also partly amorphizes the insulating layer. Because etch rates of amorphous insulator and crystalline insulator differ, the amorphized portion of the insulating layer may serve as a natural etch stop to enable even better fine-tuning of the overlap. Corresponding semiconductor devices are also provided.

Abstract: The invention relates to a semiconductor device (10) with a substrate and a semiconductor body (1) comprising a first FET (3) with a source (2) and a drain (3) that are provided with connection regions (2B, 3B) of a metal silicide, and that are connected to source and drain extensions (2A, 3A) bordering a channel region (4) below a gate (6) and having a smaller thickness and a lower doping concentration than the source (2) and the drain (3). The source (2) and drain (3) and the source and drain extensions (2A, 3A) are connected to each other by means of an intermediate region (2C, 3C) of the first conductivity type having a thickness and a doping concentration ranging between the thickness and doping concentration of the source (2) and drain (3) and the extensions (2A, 3A) thereof.

Abstract: The present invention provides an MIS type semiconductor device, comprising a semiconductor substrate and a gate electrode formed on the gate insulating film and formed of gate material. The gate electrode comprises: a first layer of activated crystalline gate material having a first side oriented towards a substrate and a second side oriented away from the substrate, the first layer of activated crystalline gate material having a doping level of 1019 ions/cm3 or higher, and a second layer of gate material at the second side of the first layer of activated crystalline gate material. The present invention also provides a method for making such a device.

Abstract: Methods of providing a semiconductor device with a control electrode structure having a controlled overlap between control electrode and first and second main electrode extensions without many spacers are disclosed. A preferred method provides a step of etching back an insulating layer performed after amorphizing and implanting the main electrode extensions. Preferably, the step that amorphizes the extensions also partly amorphizes the insulating layer. Because etch rates of amorphous insulator and crystalline insulator differ, the amorphized portion of the insulating layer may serve as a natural etch stop to enable even better fine-tuning of the overlap. Corresponding semiconductor devices are also provided.

Abstract: Methods of forming semiconductor devices with a layered structure of thin and well defined layer of activated dopants, are disclosed. In a preferred method, a region in a semiconductor substrate is amorphized, after which the region is implanted with a first dopant at a first doping concentration. Then a solid phase epitaxy regrowth step is performed on a thin layer of desired thickness of the amorphized region, in order to activate the first dopant only in this thin layer. Subsequently, a second dopant is implanted in the remaining amorphous region at a second doping concentration. Subsequent annealing of the substrate activates the second dopant only in said remaining region, so a very abrupt transition between dopant characteristics of the thin layer with first dopant and the region with the second dopant is obtained.