Abstract: An integrated circuit comprises a substrate and a buried dielectric formed in the substrate. The buried dielectric has a first thickness in a first region, a second buried dielectric thickness in a second region, and a step between the first and second regions. A semiconductor layer overlies the buried dielectric.

Abstract: An MOS device includes a gate stack overlying a semiconductor substrate and a graded source/drain region adjacent to the gate stack. The graded source/drain region includes a first grade having a first depth, a second grade spaced further apart from a channel region than the first grade, and a third grade spaced further apart from the channel region than the second grade. The depth of the second grade is between the respective depths of the first and the third grades. The MOS device further includes a silicide region on a top surface of the source/drain region wherein the silicide region has an inner edge substantially aligned with an inner edge of the third grade, and a graded gate spacer comprising an inner portion on a sidewall of the gate stack and an outer portion on a sidewall of the inner portion.

Abstract: A selectively strained MOS device such as selectively strained PMOS device making up an NMOS and PMOS device pair without affecting a strain in the NMOS device the method including providing a semiconductor substrate comprising a lower semiconductor region, an insulator region overlying the lower semiconductor region and an upper semiconductor region overlying the insulator region; patterning the upper semiconductor region and insulator region to form a MOS active region; forming an MOS device comprising a gate structure and a channel region on the MOS active region; and, carrying out an oxidation process to oxidize a portion of the upper semiconductor region to produce a strain in the channel region.

Abstract: An inductive device including an inductor coil located over a substrate, at least one electrically insulating layer interposing the inductor coil and the substrate, and a plurality of current interrupters each extending into the substrate, wherein a first aggregate outer boundary of the plurality of current interrupters substantially encompasses a second aggregate outer boundary of the inductor coil.

Abstract: A diffusion layer for semiconductor devices is provided. In accordance with embodiments of the present invention, a semiconductor device, such as a transistor, comprises doped regions surrounded by a diffusion barrier. The diffusion barrier may be formed by recessing regions of the substrate and implanting fluorine or carbon ions. A silicon layer may be epitaxially grown over the diffusion barrier in the recessed regions. Thereafter, the recessed regions may be filled and doped with a semiconductor or semiconductor alloy material. In an embodiment, a semiconductor alloy material, such as silicon carbon, is selected to induce a tensile stress in the channel region for an NMOS device, and a semiconductor alloy material, such as silicon germanium, is selected to induce a compressive stress in the channel region for a PMOS device.

Abstract: In a method of forming a double gate device, a buried insulating layer having a thickness of less than about 30 nm is formed on a first substrate. A second substrate is formed on the buried insulating layer. A pad layer is formed over the second substrate. A mask layer is formed over the pad layer. A first trench is formed extending through the pad layer, second substrate, buried insulating layer and into the first substrate. The first trench is filled with a first isolation. A second trench is formed in the first isolation and filled with a conductive material. An MOS transistor is formed on the second substrate. A bottom gate is formed under the buried insulating layer and self-aligned to the top gate formed on the second substrate.

Abstract: A method for forming a gate electrode for a multiple gate transistor provides a doped, planarized gate electrode material which may be patterned using conventional methods to produce a gate electrode that straddles the active area of the multiple gate transistor and has a constant transistor gate length. The method includes forming a layer of gate electrode material having a non-planar top surface, over a semiconductor fin. The method further includes planarizing and doping the gate electrode material, without doping the source/drain active areas, then patterning the gate electrode material. Planarization of the gate electrode material may take place prior to the introduction and activation of dopant impurities or it may follow the introduction arid activation of dopant impurities. After the gate electrode is patterned, dopant impurities are selectively introduced to the semiconductor fin to form source/drain regions.

Abstract: A method for forming a gate electrode for a multiple gate transistor provides a doped, planarized gate electrode material which may be patterned using conventional methods to produce a gate electrode that straddles the active area of the multiple gate transistor and has a constant transistor gate length. The method includes forming a layer of gate electrode material having a non-planar top surface, over a semiconductor fin. The method further includes planarizing and doping the gate electrode material, without doping the source/drain active areas, then patterning the gate electrode material. Planarization of the gate electrode material may take place prior to the introduction and activation of dopant impurities or it may follow the introduction and activation of dopant impurities. After the gate electrode is patterned, dopant impurities are selectively introduced to the semiconductor fin to form source/drain regions.

Abstract: Differentially strained active regions for forming strained channel semiconductor devices and a method of forming the same, the method including providing a semiconductor substrate comprising a lower semiconductor region, an insulator region overlying the lower semiconductor region and an upper semiconductor region overlying the insulator region; forming a doped area of the insulator region underlying a subsequently formed NMOS active region; patterning the upper semiconductor region to form the NMOS active region and a PMOS active region; carrying out a thermal oxidation process to produce a differential-volume expansion in the PMOS active region with respect to the NMOS active region; forming recessed areas comprising the insulator region adjacent either side of the PMOS active region; and, removing layers overlying the upper semiconductor region to produce differentially strained regions comprising the PMOS and NMOS active regions.

Abstract: A method of forming a multiple-thickness semiconductor-on-insulator, comprising the following steps. A wafer is provided comprising a semiconductor film (having at least two regions) overlying a buried insulator layer overlying a substrate. The semiconductor film within one of the at least two regions is masked to provide at least one semiconductor film masked portion having a first thickness, leaving exposed the semiconductor film within at least one of the at least two regions to provide at least one semiconductor film exposed portion having the first thickness. In one embodiment, at least a portion of the at least one exposed semiconductor film portion is oxidized to provide at least one partially oxidized, exposed semiconductor film portion. Then the oxidized portion of the exposed semiconductor film is removed to leave a portion of the semiconductor film having a second thickness less than the first thickness.

Abstract: Differentially strained active regions for forming strained channel semiconductor devices and a method of forming the same, the method including providing a semiconductor substrate comprising a lower semiconductor region, an insulator region overlying the lower semiconductor region and an upper semiconductor region overlying the insulator region; forming a doped area of the insulator region underlying a subsequently formed NMOS active region; patterning the upper semiconductor region to form the NMOS active region and a PMOS active region; carrying out a thermal oxidation process to produce a differential volume expansion in the PMOS active region with respect to the NMOS active region; forming recessed areas comprising the insulator region adjacent either side of the PMOS active region; and, removing layers overlying the upper semiconductor region to produce differentially strained regions comprising the PMOS and NMOS active regions.

Abstract: A semiconductor structure includes of a plurality of semiconductor fins overlying an insulator layer, a gate dielectric overlying a portion of said semiconductor fin, and a gate electrode overlying the gate dielectric. Each of the semiconductor fins has a top surface, a first sidewall surface, and a second sidewall surface. Dopant ions are implanted at a first angle (e.g., greater than about 7°) with respect to the normal of the top surface of the semiconductor fin to dope the first sidewall surface and the top surface. Further dopant ions are implanted with respect to the normal of the top surface of the semiconductor fin to dope the second sidewall surface and the top surface.

Abstract: A semiconductor structure includes of a plurality of semiconductor fins overlying an insulator layer, a gate dielectric overlying a portion of said semiconductor fin, and a gate electrode overlying the gate dielectric. Each of the semiconductor fins has a top surface, a first sidewall surface, and a second sidewall surface. Dopant ions are implanted at a first angle (e.g., greater than about 7°) with respect to the normal of the top surface of the semiconductor fin to dope the first sidewall surface and the top surface. Further dopant ions are implanted with respect to the normal of the top surface of the semiconductor fin to dope the second sidewall surface and the top surface.

Abstract: Differentially strained active regions for forming strained channel semiconductor devices and a method of forming the same, the method including providing a semiconductor substrate comprising a lower semiconductor region, an insulator region overlying the lower semiconductor region and an upper semiconductor region overlying the insulator region; forming a doped area of the insulator region underlying a subsequently formed NMOS active region; patterning the upper semiconductor region to form the NMOS active region and a PMOS active region; carrying out a thermal oxidation process to produce a differential volume expansion in the PMOS active region with respect to the NMOS active region; forming recessed areas comprising the insulator region adjacent either side of the PMOS active region; and, removing layers overlying the upper semiconductor region to produce differentially strained regions comprising the PMOS and NMOS active regions.

Abstract: This invention discloses a method and a semiconductor structure for integrating at least one bulk device and at least one silicon-on-insulator (SOI) device. The semiconductor structure includes a first substrate having an SOI area and a bulk area, on which the bulk device is formed; an insulation layer formed on the first substrate in the SOI area; and a second substrate, on which the SOI device is formed, stacked on the insulation layer. The surface of the first substrate is not on the substantially same plane as the surface of the second substrate.

Abstract: A semiconductor structure includes of a plurality of semiconductor fins overlying an insulator layer, a gate dielectric overlying a portion of said semiconductor fin, and a gate electrode overlying the gate dielectric. Each of the semiconductor fins has a top surface, a first sidewall surface, and a second sidewall surface. Dopant ions are implanted at a first angle (e.g., greater than about 7°) with respect to the normal of the top surface of the semiconductor fin to dope the first sidewall surface and the top surface. Further dopant ions are implanted with respect to the normal of the top surface of the semiconductor fin to dope the second sidewall surface and the top surface.

Abstract: In a method of forming a double gate device, a buried insulating layer having a thickness of less than about 30 nm is formed on a first substrate. A second substrate is formed on the buried insulating layer. A pad layer is formed over the second substrate. A mask layer is formed over the pad layer. A first trench is formed extending through the pad layer, second substrate, buried insulating layer and into the first substrate. The first trench is filled with a first isolation. A second trench is formed in the first isolation and filled with a conductive material. An MOS transistor is formed on the second substrate. A bottom gate is formed under the buried insulating layer and self-aligned to the top gate formed on the second substrate.

Abstract: This invention discloses a method and a semiconductor structure for integrating at least one bulk device and at least one silicon-on-insulator (SOI) device. The semiconductor structure includes a first substrate having an SOI area and a bulk area, on which the bulk device is formed; an insulation layer formed on the first substrate in the SOI area; and a second substrate, on which the SOI device is formed, stacked on the insulation layer. The surface of the first substrate is not on the substantially same plane as the surface of the second substrate.

Abstract: An inductive device including an inductor coil located over a substrate, at least one electrically insulating layer interposing the inductor coil and the substrate, and a plurality of current interrupters each extending into the substrate, wherein a first aggregate outer boundary of the plurality of current interrupters substantially encompasses a second aggregate outer boundary of the inductor coil.

Abstract: A semiconductor-on-insulator structure includes a substrate and a buried insulator layer overlying the substrate. A plurality of semiconductor islands overlie the buried insulator layer. The semiconductor islands are isolated from one another by trenches. A plurality of recess resistant regions overlie the buried insulator layer at a lower surface of the trenches.