Abstract: A method of making a Silicon-on-Insulator (SOI) transistor includes forming a body layer that is fully depleted when the SOI transistor is in a conductive state and forming first p+ regions adjacent each of the SOI transistor source/drain regions to adjust the SOI transistor threshold voltage. To suppress punch-through current, an additional implant step is carried out to form second p+ regions adjacent first implant regions.

Abstract: A silicon-on-insulator (SOI) device with a strained silicon film has a substrate, and a buried oxide layer on the substrate. Silicon islands are formed on the buried oxide layer, the silicon islands being separated from each other by gaps. The buried oxide layers has recesses directly under the gaps. A material fills the recesses and the gaps, this material being different from the material forming the buried oxide layer. The material induces a net amount of strain in the silicon islands, thereby modifying the electrical properties of carriers in the silicon film and improving device performance.

Abstract: A silicon-on-insulator (SOI) device with a strained silicon film has a substrate, and a buried oxide layer on the substrate. Silicon islands are formed on the buried oxide layer, the silicon islands being separated from each other by gaps. The buried oxide layers has recesses directly under the gaps. A material fills the recesses and the gaps, this material being different from the material forming the buried oxide layer. The material induces a net amount of strain in the silicon islands, thereby modifying the electrical properties of carriers in the silicon film and improving device performance.

Abstract: An asymmetric semiconductor device and a method of making a pair of the asymmetric devices. The semiconductor device includes a layer of semiconductor material having a source and a drain, and a dual work function gate disposed on the layer of semiconductor material to define a channel interposed between the source and the drain.

Abstract: An asymmetric semiconductor device and a method of making a pair of the asymmetric devices. The semiconductor device includes a layer of semiconductor material having a source and a drain, and a dual work function gate disposed on the layer of semiconductor material to define a channel interposed between the source and the drain.

Abstract: A MOSFET and methods of fabrication. The MOSFET includes a gate having a center gate electrode portion being spaced from the layer of semiconductor material by a center gate dielectric. The gate also includes a lateral gate electrode portion adjacent each sidewall of the center gate electrode portion. The lateral gate electrode portions are each spaced from the layer of semiconductor material by a lateral gate dielectric portion.

Abstract: A Silicon-on-Insulator (SOI) transistor includes an intrinsic body layer that is fully depleted when in a conductive state. The transistor includes a shallow pocket of dopants adjacent to each of its source and drain regions. The shallow pockets are of a conductivity type opposite to that of the source and drain regions and raise the threshold voltage of the transistor. The transistor also includes a deep pocket of dopants adjacent each of the source and drain regions to suppress the punch-through current.

Abstract: Floating body effects are substantially reduced by strategically forming source-side stacking faults to create a leakage path from the body to the source of an SOI structure. Embodiments include ion implanting a heavy ion, such as Xe, to form a buried amorphous layer in the source-side of the silicon layer after source/drain implants followed by silicidation, during which the buried amorphous region recrystallizes creating source-side stacking faults.

Abstract: A method of forming a MOSFET device is provided including the steps of forming N− lightly doped source and drain extension regions in the top silicon layer, forming spacers above the N− lightly doped source and drain extension regions and forming N+ source and N+ drain regions in the top silicon layer. A silicide film is then provided over the drain and source regions and the spacers are removed. An ion implantation step is then performed to form damaged sidewall regions in the source body and drain body junction.

Abstract: A method of isolation of active islands on a silicon-on-insulator semiconductor device, comprising the steps of (a) providing a silicon-on-insulator semiconductor wafer having a silicon active layer, a dielectric isolation layer and a silicon substrate, in which the silicon active layer is formed on the dielectric isolation layer and the dielectric isolation layer is formed on the silicon substrate; (b) etching the silicon active layer to form an isolation trench wherein an unetched silicon layer at bottom of the isolation trench remains; (c) oxidizing the layer of silicon at the bottom of the isolation trench to a degree sufficient to oxidize through the layer of silicon at the bottom to the dielectric isolation layer; and (d) filling the isolation trench with a trench isolation material to form a shallow trench isolation structure.

Abstract: A semiconductor-on-insulator (SOI) device. The SOI device includes a semiconductor substrate layer; an insulator layer disposed on the substrate layer; a semiconductor active region disposed on the insulator layer, the active region including a source, a drain, and a body disposed therebetween, at least one of the source and the drain forming a hyperabrupt junction with the body; and a gate disposed on the body such that the gate, source, drain and body are operatively arranged to form a transistor. The at least one of the source and drain forming the hyperabrupt junction with the body includes a silicide region. The silicide region has a generally vertical interface, which is laterally spaced apart from the hyperabrupt junction by about 60 Å to about 150 Å.

Abstract: The present invention relates to a method of manufacturing a semiconductor device, including the steps of providing a silicon-on-insulator semiconductor wafer having a silicon film formed on an insulator layer; forming a semiconductor device in the silicon film, the semiconductor device including a semiconductor element, an interlayer dielectric over the semiconductor device, and at least one opening passing through the interlayer dielectric and in communication with the semiconductor element; implanting inert atoms into the semiconductor element by passing the inert atoms through the opening at an energy and at a dose sufficient to form a damaged region in the semiconductor element, wherein the oxide insulating layer acts as a mask to block implantation of the inert atoms into other portions of the semiconductor device, and the damaged region comprises gettering sites; and subjecting the semiconductor device to conditions to getter at least one impurity into the gettering sites from adjacent portions of the

Abstract: A method of forming a semiconductor-on-insulator (SOI) device. The method includes providing an SOI wafer having an active layer, a substrate and a buried insulator layer therebetween; defining an active region in the active layer; forming a source, a drain and body in the active region, the source and the drain forming respective hyperabrupt junctions with the body, the hyperabrupt junctions being formed by an SPE process which includes amorphizing the at least one of the source and the drain, implanting dopant ion species and recrystalizing at temperature of less than 700° C.; forming a gate disposed on the body such that the source, drain, body and gate are operatively arranged to form a transistor; and forming a silicide region in each of the source and the drain, the silicide regions being spaced from the respective hyperabrupt junctions by a lateral distance of less than about 100 Å.

Abstract: A shallow abrupt junction is formed in a single crystal substrate, for example, to form a pn junction in a diode or a source drain extension in a transistor. An amorphous layer is formed at the surface of the substrate by implanting an electrically inactive ion, such as germanium or silicon, into the substrate. The amorphous/crystalline interface between the amorphous layer and the base crystal substrate is located at the depth of the desired junction. A dopant species, such as boron, phosphorus or arsenic is implanted into the substrate so that peak concentration of the dopant is at least partially within the amorphous layer. The amorphous layer can be formed either before or after the implanting of the dopant species. A low temperature anneal is used to recrystallize the amorphous layer through solid phase epitaxy, which also activates the dopant within the amorphous layer. The dopant located beneath the original amorphous/crystalline interface remains inactive.

Abstract: A method for processing a semiconductor wafer transforms the wafer into one which has a plurality of surface semiconductor platforms for formation of integrated circuit elements thereupon. The platforms are connected to a subsurface bulk layer of semiconductor material via integrally-formed bridges of semiconductor material. The platforms are otherwise surrounded with an electrically-insulating material, thereby providing good insulation between adjacent of the platforms. The method includes the steps of placing a mask on a wafer surface of the wafer, forming a subsurface altered material beneath portions of the wafer surface not covered by the mask, creating exposure openings through the wafer surface to expose a portion of the subsurface altered material, selectively removing the subsurface altered material by selective etching, and filling the subsurface regions and the exposure openings with an electrically-insulating material. In an exemplary embodiment the mask includes a plurality of gate conductors.

Abstract: A method (100) of forming a transistor (50, 80) includes forming a gate oxide (120) over a portion of a semiconductor material (56, 122) and forming a doped polysilicon film (124) having a dopant concentration over the gate oxide (122). Subsequently, the doped polysilicon film (124) is etched to form a gate electrode (52) overlying a channel region (58) in the semiconductor material (56, 122), wherein the gate electrode (52) separates the semiconductor material into a first region (60) and a second region (68) having the channel region (58) therebetween. The method (100) further includes forming a drain extension region (64) in the first region (60) and a source extension region (72) in the second region (68), and forming a drain region (62) in the first region (60) and a source region (70) in the second region (68). The source/drain formation is such that the drain and source regions (62, 70) have a dopant concentration which is less than the polysilicon film (124) doping concentration.

Abstract: A method of forming a MOSFET device is provided. First lightly doped regions are formed, the first lightly doped regions including LDD extension regions of the device. Second very lightly doped regions are formed at least partially below the first lightly doped regions, respectively, the second very lightly doped regions having a dopant concentration less than the first lightly doped regions, and the second very lightly doped regions being implanted at a higher energy level than the first lightly doped regions.

Abstract: In accordance with the present invention, an amorphous layer is formed in a crystalline substrate (e.g., the channel region of a MOSFET transistor) by, for example, implanting ions of an inert specie such as germanium. A dopant is implanted so that it overlaps with the amorphous layer. Subsequently, low temperature recrystallization of the amorphous layer leads to an abrupt retrograded layer of active dopant in the channel region of the MOSFET. This retrograded dopant layer could be formed before or after the formation of the gate electrode.

Abstract: A method (100) of forming a transistor (50, 80) includes forming a gate oxide (120) over a portion of a semiconductor material (56, 122) and forming a doped polysilicon film (124) having a dopant concentration over the gate oxide (122). Subsequently, the doped polysilicon film (124) is etched to form a gate electrode (52) overlying a channel region (58) in the semiconductor material (56, 122), wherein the gate electrode (52) separates the semiconductor material into a first region (60) and a second region (68) having the channel region (58) therebetween. The method (100) further includes forming a drain extension region (64) in the first region (60) and a source extension region (72) in the second region (68), and forming a drain region (62) in the first region (60) and a source region (70) in the second region (68). The source/drain formation is such that the drain and source regions (62, 70) have a dopant concentration which is less than the polysilicon film (124) doping concentration.

Abstract: A method for the self-aligned thickening of the source and drain contact regions (24,26) in which an amorphous silicon layer (40) is deposited over the gate (16), source contact region (24), the drain contact region (26), and side wall spacer (20) of an FET being fabricated on a substrate silicon layer (14). The amorphous layer (40) is heated to induce epitaxial growth in the source contact region (24) and drain contact region (26). The induced epitaxial growth of the amorphous silicon thickens these contact regions allowing for the subsequent formation of a highly conductive contact silicide for the cases where the available volume of the silicon in the contact areas is limited. The uncrystallized silicon is removed from the side wall spacer (20) of the gate and other insulating areas by a selective wet etch.