Patent application number | Description | Published |
20090020792 | ISOLATED TRI-GATE TRANSISTOR FABRICATED ON BULK SUBSTRATE - A method of forming an isolated tri-gate semiconductor body comprises patterning a bulk substrate to form a fin structure, depositing an insulating material around the fin structure, recessing the insulating material to expose a portion of the fin structure that will be used for the tri-gate semiconductor body, depositing a nitride cap over the exposed portion of the fin structure to protect the exposed portion of the fin structure, and carrying out a thermal oxidation process to oxidize an unprotected portion of the fin structure below the nitride cap. The oxidized portion of the fin isolates the semiconductor body that is being protected by the nitride cap. The nitride cap may then be removed. The thermal oxidation process may comprise annealing the substrate at a temperature between around 900° C. and around 1100° C. for a time duration between around 0.5 hours and around 3 hours. | 01-22-2009 |
20090032872 | MULTIPLE OXIDE THICKNESS FOR A SEMICONDUCTOR DEVICE - Techniques associated with providing multiple gate insulator thickness for a semiconductor device are generally described. In one example, an apparatus includes a semiconductor fin having an impurity introduced to at least a first side of the fin, a first oxide having a first thickness coupled with the first side of the fin, and a second oxide having a second thickness coupled with a second side of the fin, the second thickness being different from the first thickness as a result of the impurity introduced to the first side of the fin. | 02-05-2009 |
20090152589 | Systems And Methods To Increase Uniaxial Compressive Stress In Tri-Gate Transistors - A transistor structure that increases uniaxial compressive stress on the channel region of a tri-gate transistor comprises at least two semiconductor bodies formed on a substrate, each semiconductor body having a pair of laterally opposite sidewalls and a top surface, a common source region formed on one end of the semiconductor bodies, wherein the common source region is coupled to all of the at least two semiconductor bodies, a common drain region formed on another end of the semiconductor bodies, wherein the common drain region is coupled to all of the at least two semiconductor bodies, and a common gate electrode formed over the at least two semiconductor bodies, wherein the common gate electrode provides a gate electrode for each of the at least two semiconductor bodies and wherein the common gate electrode has a pair of laterally opposite sidewalls that are substantially perpendicular to the sidewalls of the semiconductor bodies. | 06-18-2009 |
20100059821 | Isolated tri-gate transistor fabricated on bulk substrate - A method of forming an isolated tri-gate semiconductor body comprises patterning a bulk substrate to form a fin structure, depositing an insulating material around the fin structure, recessing the insulating material to expose a portion of the fin structure that will be used for the tri-gate semiconductor body, depositing a nitride cap over the exposed portion of the fin structure to protect the exposed portion of the fin structure, and carrying out a thermal oxidation process to oxidize an unprotected portion of the fin structure below the nitride cap. The oxidized portion of the fin isolates the semiconductor body that is being protected by the nitride cap. The nitride cap may then be removed. The thermal oxidation process may comprise annealing the substrate at a temperature between around 900° C. and around 1100° C. for a time duration between around 0.5 hours and around 3 hours. | 03-11-2010 |
20100163970 | Trigate transistor having extended metal gate electrode - A trigate device having an extended metal gate electrode comprises a semiconductor body having a top surface and opposing sidewalls formed on a substrate, an isolation layer formed on the substrate and around the semiconductor body, wherein a portion of the semiconductor body remains exposed above the isolation layer, and a gate stack formed on the top surface and opposing sidewalls of the semiconductor body, wherein the gate stack extends a depth into the isolation layer, thereby causing a bottom surface of the gate stack to be below a top surface of the isolation layer. | 07-01-2010 |
20110147811 | TWO-DIMENSIONAL CONDENSATION FOR UNIAXIALLY STRAINED SEMICONDUCTOR FINS - Techniques are disclosed for enabling multi-sided condensation of semiconductor fins. The techniques can be employed, for instance, in fabricating fin-based transistors. In one example case, a strain layer is provided on a bulk substrate. The strain layer is associated with a critical thickness that is dependent on a component of the strain layer, and the strain layer has a thickness lower than or equal to the critical thickness. A fin is formed in the substrate and strain layer, such that the fin includes a substrate portion and a strain layer portion. The fin is oxidized to condense the strain layer portion of the fin, so that a concentration of the component in the strain layer changes from a pre-condensation concentration to a higher post-condensation concentration, thereby causing the critical thickness to be exceeded. | 06-23-2011 |
20110147840 | WRAP-AROUND CONTACTS FOR FINFET AND TRI-GATE DEVICES - A semiconductor device comprises a substrate and a semiconductor body formed on the substrate. The semiconductor body comprises a source region; and a drain region. The source region or the drain region, or combinations thereof, comprises a first side surface, a second side surface, and a top surface. The first side surface is opposite the second side surface, the top surface is opposite the bottom surface. The source region or the drain region, or combinations thereof, comprise a metal layer formed on the substantially all of the first side surface, substantially all of the second side surface, and the top surface. | 06-23-2011 |
20110147847 | Methods and apparatus to reduce layout based strain variations in non-planar transistor structures - The present disclosure relates to the field of fabricating microelectronic devices. In at least one embodiment, the present disclosure relates to forming isolation structures in strained semiconductor bodies of non-planar transistors while maintaining strain in the semiconductor bodies. | 06-23-2011 |
20120074464 | Non-planar device having uniaxially strained semiconductor body and method of making same - A method and a device made according to the method. The method comprises providing a substrate including a first material, and providing a fin including a second material, the fin being disposed on the substrate and having a device active portion, the first material and the second material presenting a lattice mismatch between respective crystalline structures thereof. Providing the fin includes providing a biaxially strained film including the second material on the substrate; and removing parts of the biaxially strained film to form a substantially uniaxially strained fin therefrom. | 03-29-2012 |
20120138886 | SILICON AND SILICON GERMANIUM NANOWIRE STRUCTURES - Methods of forming microelectronic structures are described. Embodiments of those methods include forming a nanowire device comprising a substrate comprising source/drain structures adjacent to spacers, and nanowire channel structures disposed between the spacers, wherein the nanowire channel structures are vertically stacked above each other. | 06-07-2012 |
20120241818 | TWO-DIMENSIONAL CONDENSATION FOR UNIAXIALLY STRAINED SEMICONDUCTOR FINS - Techniques are disclosed for enabling multi-sided condensation of semiconductor fins. The techniques can be employed, for instance, in fabricating fin-based transistors. In one example case, a strain layer is provided on a bulk substrate. The strain layer is associated with a critical thickness that is dependent on a component of the strain layer, and the strain layer has a thickness lower than or equal to the critical thickness. A fin is formed in the substrate and strain layer, such that the fin includes a substrate portion and a strain layer portion. The fin is oxidized to condense the strain layer portion of the fin, so that a concentration of the component in the strain layer changes from a pre-condensation concentration to a higher post-condensation concentration, thereby causing the critical thickness to be exceeded. | 09-27-2012 |
20120305990 | METHODS AND APPARATUS TO REDUCE LAYOUT BASED STRAIN VARIATIONS IN NON-PLANAR TRANSISTOR STRUCTURES - The present disclosure relates to the field of fabricating microelectronic devices. In at least one embodiment, the present disclosure relates to forming isolation structures in strained semiconductor bodies of non-planar transistors while maintaining strain in the semiconductor bodies. | 12-06-2012 |
20130320455 | SEMICONDUCTOR DEVICE WITH ISOLATED BODY PORTION - Semiconductor devices with isolated body portions are described. For example, a semiconductor structure includes a semiconductor body disposed above a semiconductor substrate. The semiconductor body includes a channel region and a pair of source and drain regions on either side of the channel region. An isolation pedestal is disposed between the semiconductor body and the semiconductor substrate. A gate electrode stack at least partially surrounds a portion of the channel region of the semiconductor body. | 12-05-2013 |
20140001572 | THROUGH GATE FIN ISOLATION | 01-02-2014 |
20140027816 | HIGH MOBILITY STRAINED CHANNELS FOR FIN-BASED TRANSISTORS - Techniques are disclosed for incorporating high mobility strained channels into fin-based transistors (e.g., FinFETs such as double-gate, trigate, etc), wherein a stress material is cladded onto the channel area of the fin. In one example embodiment, silicon germanium (SiGe) is cladded onto silicon fins to provide a desired stress, although other fin and cladding materials can be used. The techniques are compatible with typical process flows, and the cladding deposition can occur at a plurality of locations within the process flow. In some cases, the built-in stress from the cladding layer may be enhanced with a source/drain stressor that compresses both the fin and cladding layers in the channel. In some cases, an optional capping layer can be provided to improve the gate dielectric/semiconductor interface. In one such embodiment, silicon is provided over a SiGe cladding layer to improve the gate dielectric/semiconductor interface. | 01-30-2014 |
20140042386 | NANOWIRE STRUCTURES HAVING NON-DISCRETE SOURCE AND DRAIN REGIONS - Nanowire structures having non-discrete source and drain regions are described. For example, a semiconductor device includes a plurality of vertically stacked nanowires disposed above a substrate. Each of the nanowires includes a discrete channel region disposed in the nanowire. A gate electrode stack surrounds the plurality of vertically stacked nanowires. A pair of non-discrete source and drain regions is disposed on either side of, and adjoining, the discrete channel regions of the plurality of vertically stacked nanowires. | 02-13-2014 |
20140070273 | Non-Planar Device Having Uniaxially Strained Semiconductor Body and Method of Making Same - A method and a device made according to the method. The method comprises providing a substrate including a first material, and providing a fin including a second material, the fin being disposed on the substrate and having a device active portion, the first material and the second material presenting a lattice mismatch between respective crystalline structures thereof. Providing the fin includes providing a biaxially strained film including the second material on the substrate; and removing parts of the biaxially strained film to form a substantially uniaxially strained fin therefrom. | 03-13-2014 |
20140131660 | UNIAXIALLY STRAINED NANOWIRE STRUCTURE - Uniaxially strained nanowire structures are described. For example, a semiconductor device includes a plurality of vertically stacked uniaxially strained nanowires disposed above a substrate. Each of the uniaxially strained nanowires includes a discrete channel region disposed in the uniaxially strained nanowire. The discrete channel region has a current flow direction along the direction of the uniaxial strain. Source and drain regions are disposed in the nanowire, on either side of the discrete channel region. A gate electrode stack completely surrounds the discrete channel regions. | 05-15-2014 |
20140138744 | TUNNELING FIELD EFFECT TRANSISTORS (TFETS) FOR CMOS ARCHITECTURES AND APPROACHES TO FABRICATING N-TYPE AND P-TYPE TFETS - Tunneling field effect transistors (TFETs) for CMOS architectures and approaches to fabricating N-type and P-type TFETs are described. For example, a tunneling field effect transistor (TFET) includes a homojunction active region disposed above a substrate. The homojunction active region includes a relaxed Ge or GeSn body having an undoped channel region therein. The homojunction active region also includes doped source and drain regions disposed in the relaxed Ge or GeSn body, on either side of the channel region. The TFET also includes a gate stack disposed on the channel region, between the source and drain regions. The gate stack includes a gate dielectric portion and gate electrode portion. | 05-22-2014 |
20140175543 | CONVERSION OF THIN TRANSISTOR ELEMENTS FROM SILICON TO SILICON GERMANIUM - Embodiments of the present disclosure provide techniques and configurations associated with conversion of thin transistor elements from silicon (Si) to silicon germanium (SiGe). In one embodiment, a method includes providing a semiconductor substrate having a channel body of a transistor device disposed on the semiconductor substrate, the channel body comprising silicon, forming a cladding layer comprising germanium on the channel body, and annealing the channel body to cause the germanium to diffuse into the channel body. Other embodiments may be described and/or claimed. | 06-26-2014 |
20140197377 | CMOS NANOWIRE STRUCTURE - Complimentary metal-oxide-semiconductor nanowire structures are described. For example, a semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first nanowire disposed above a substrate. The first nanowire has a mid-point a first distance above the substrate and includes a discrete channel region and source and drain regions on either side of the discrete channel region. A first gate electrode stack completely surrounds the discrete channel region of the first nanowire. The semiconductor structure also includes a second semiconductor device. The second semiconductor device includes a second nanowire disposed above the substrate. The second nanowire has a mid-point a second distance above the substrate and includes a discrete channel region and source and drain regions on either side of the discrete channel region. The first distance is different from the second distance. A second gate electrode stack completely surrounds the discrete channel region of the second nanowire. | 07-17-2014 |
20140209855 | NANOWIRE STRUCTURES HAVING WRAP-AROUND CONTACTS - Nanowire structures having wrap-around contacts are described. For example, a nanowire semiconductor device includes a nanowire disposed above a substrate. A channel region is disposed in the nanowire. The channel region has a length and a perimeter orthogonal to the length. A gate electrode stack surrounds the entire perimeter of the channel region. A pair of source and drain regions is disposed in the nanowire, on either side of the channel region. Each of the source and drain regions has a perimeter orthogonal to the length of the channel region. A first contact completely surrounds the perimeter of the source region. A second contact completely surrounds the perimeter of the drain region. | 07-31-2014 |
20140285980 | CONVERSION OF STRAIN-INDUCING BUFFER TO ELECTRICAL INSULATOR - Techniques are disclosed for converting a strain-inducing semiconductor buffer layer into an electrical insulator at one or more locations of the buffer layer, thereby allowing an above device layer to have a number of benefits, which in some embodiments include those that arise from being grown on a strain-inducing buffer and having a buried electrical insulator layer. For instance, having a buried electrical insulator layer (initially used as a strain-inducing buffer during fabrication of the above active device layer) between the Fin and substrate of a non-planar integrated transistor circuit may simultaneously enable a low-doped Fin with high mobility, desirable device electrostatics and elimination or otherwise reduction of substrate junction leakage. Also, the presence of such an electrical insulator under the source and drain regions may further significantly reduce junction leakage. In some embodiments, substantially the entire buffer layer is converted to an electrical insulator. | 09-25-2014 |
20140326952 | SILICON AND SILICON GERMANIUM NANOWIRE STRUCTURES - Methods of forming microelectronic structures are described. Embodiments of those methods include forming a nanowire device comprising a substrate comprising source/drain structures adjacent to spacers, and nanowire channel structures disposed between the spacers, wherein the nanowire channel structures are vertically stacked above each other. | 11-06-2014 |
20150041847 | TUNNELING FIELD EFFECT TRANSISTORS (TFETS) FOR CMOS ARCHITECTURES AND APPROACHES TO FABRICATING N-TYPE AND P-TYPE TFETS - Tunneling field effect transistors (TFETs) for CMOS architectures and approaches to fabricating N-type and P-type TFETs are described. For example, a tunneling field effect transistor (TFET) includes a homojunction active region disposed above a substrate. The homojunction active region includes a relaxed Ge or GeSn body having an undoped channel region therein. The homojunction active region also includes doped source and drain regions disposed in the relaxed Ge or GeSn body, on either side of the channel region. The TFET also includes a gate stack disposed on the channel region, between the source and drain regions. The gate stack includes a gate dielectric portion and gate electrode portion. | 02-12-2015 |