Patent application number | Description | Published |
20110121398 | TECHNIQUE FOR ENHANCING DOPANT PROFILE AND CHANNEL CONDUCTIVITY BY MILLISECOND ANNEAL PROCESSES - During the fabrication of advanced transistors, significant dopant diffusion may be suppressed by performing a millisecond anneal process after completing the basic transistor configuration, wherein a stress memorization technique may also be obtained by forming a strain-inducing area within a sidewall spacer structure. Due to the corresponding void formation in the spacer structure, a high tensile strain component may be obtained in the adjacent channel region. | 05-26-2011 |
20120146155 | TECHNIQUE FOR ENHANCING DOPANT PROFILE AND CHANNEL CONDUCTIVITY BY MILLISECOND ANNEAL PROCESSES - During the fabrication of advanced transistors, significant dopant diffusion may be suppressed by performing a millisecond anneal process after completing the basic transistor configuration, wherein a stress memorization technique may also be obtained by forming a strain-inducing area within a sidewall spacer structure. Due to the corresponding void formation in the spacer structure, a high tensile strain component may be obtained, in the adjacent channel region. | 06-14-2012 |
20120231591 | METHODS FOR FABRICATING CMOS INTEGRATED CIRCUITS HAVING METAL SILICIDE CONTACTS - Methods are provided for fabricating CMOS integrated circuits. In accordance with one embodiment the methods include forming a gate electrode structure overlying an N-doped portion of a semiconductor substrate and growing an embedded silicon germanium area in the N-doped portion in alignment with the gate electrode structure. A layer of silicon is selectively grown overlying the embedded silicon germanium area and a nickel silicide contact is made to the layer of silicon. | 09-13-2012 |
20130029463 | Methods of Forming a PMOS Device with In Situ Doped Epitaxial Source/Drain Regions - Disclosed herein is a method of forming a semiconductor device. In one example, the method includes forming extension implant regions in a PMOS region and a NMOS region of a semiconducting substrate for a PMOS device and a NMOS device, respectively and, after forming the extension implant regions, performing a first heating process. The method further includes forming a plurality of cavities in the PMOS region of the substrate, performing at least one epitaxial deposition process to form a plurality of in-situ doped semiconductor layers that are positioned in or above each of said cavities, and forming a masking layer that exposes the NMOS region and covers the PMOS region. The method concludes with the steps of forming source/drain implant regions in the NMOS region of the substrate for the NMOS device and performing a second heating process. | 01-31-2013 |
20130032877 | N-CHANNEL TRANSISTOR COMPRISING A HIGH-K METAL GATE ELECTRODE STRUCTURE AND A REDUCED SERIES RESISTANCE BY EPITAXIALLY FORMED SEMICONDUCTOR MATERIAL IN THE DRAIN AND SOURCE AREAS - When forming sophisticated semiconductor devices including high-k metal gate electrode structures and N-channel transistors, superior performance may be achieved by incorporating epitaxially grown semiconductor materials, for instance a strain-inducing silicon/carbon alloy in combination with an N-doped silicon material, which may provide an acceptable sheet resistivity. | 02-07-2013 |
20130049126 | Methods of Forming a Semiconductor Device with Recessed Source/Drain Regions, and a Semiconductor Device Comprising Same - In one example, a method disclosed herein includes forming a gate electrode structure for a PMOS transistor and a gate electrode structure for a NMOS transistor, forming a plurality of cavities in the substrate proximate the gate electrode structure of the PMOS transistor and performing an epitaxial deposition process to form raised silicon-germanium regions is the cavities. The method concludes with the step of performing a common etching process on the PMOS transistor and the NMOS transistor to define recessed regions in the substrate proximate the gate electrode structure of the NMOS transistor and to reduce the amount of the silicon-germanium material positioned above the surface of the substrate for the PMOS transistor. | 02-28-2013 |
20130052782 | Implantation of Hydrogen to Improve Gate Insulation Layer-Substrate Interface - Generally, the present disclosure is directed to various methods of making a semiconductor device by implanting hydrogen or hydrogen-containing clusters to improve the interface between a gate insulation layer and the substrate. One illustrative method disclosed herein involves forming a gate insulation layer on a substrate, forming a layer of gate electrode material above the gate insulation material and performing an ion implantation process with a material comprising hydrogen or a hydrogen-containing compound to introduce the hydrogen or hydrogen-containing compound proximate an interface between the gate insulation layer and said substrate with a concentration of the implanted hydrogen or hydrogen-containing compound being at least 1e | 02-28-2013 |
20130052783 | Methods of Forming Stressed Silicon-Carbon Areas in an NMOS Transistor - Disclosed herein are various methods of forming stressed silicon-carbon areas in an NMOS transistor device. In one example, a method disclosed herein includes forming a layer of amorphous carbon above a surface of a semiconducting substrate comprising a plurality of N-doped regions and performing an ion implantation process on the layer of amorphous carbon to dislodge carbon atoms from the layer of amorphous carbon and to drive the dislodged carbon atoms into the N-doped regions in the substrate. | 02-28-2013 |
20130069123 | CMOS SEMICONDUCTOR DEVICES HAVING STRESSOR REGIONS AND RELATED FABRICATION METHODS - Semiconductor devices and related fabrication methods are provided. An exemplary fabrication method involves forming first doped stressor regions in a first region of semiconductor material, forming second doped stressor regions in a second region of semiconductor material after forming the first doped stressor regions, and after forming the second doped stressor regions, annealing the semiconductor device structure to activate ions of the first and second doped stressor regions concurrently. The amount of time for the annealing is chosen to inhibit diffusion of the ions of the first and second doped stressor regions. | 03-21-2013 |
20130175640 | STRESS ENHANCED MOS TRANSISTOR AND METHODS FOR FABRICATION - A stress enhanced MOS transistor and methods for its fabrication are provided. In one embodiment the transistor includes a channel region at a surface of a semiconductor substrate. The method includes etching first recesses into the semiconductor substrate adjacent the channel region to define adjacent regions in the semiconductor substrate between the first recesses and the channel region. A first layer of SiGe is epitaxially grown in the first recesses. The method includes etching second recesses through the first layer of SiGe and into the adjacent regions of the semiconductor substrate. Further, a second layer of SiGe is epitaxially grown in the second recesses. | 07-11-2013 |
20130178024 | In Situ Doping and Diffusionless Annealing of Embedded Stressor Regions in PMOS and NMOS Devices - Generally, the present disclosure is directed to methods for forming dual embedded stressor regions in semiconductor devices such as transistor elements and the like, using in situ doping and substantially diffusionless annealing techniques. One illustrative method disclosed herein includes forming first and second cavities in PMOS and NMOS device regions, respectively, of a semiconductor substrate, and thereafter performing first and second epitaxial deposition processes to form in situ doped first and second embedded material regions in the first and second cavities, respectively. The method further includes, among other things, performing a single heat treating process to activate dopants in the in situ doped first and second embedded material regions. | 07-11-2013 |
20130181299 | Strain Engineering in Three-Dimensional Transistors Based on Strained Isolation Material - In a three-dimensional transistor configuration, a strain-inducing isolation material is provided, at least in the drain and source areas, thereby inducing a strain, in particular at and in the vicinity of the PN junctions of the three-dimensional transistor. In this case, superior transistor performance may be achieved, while in some illustrative embodiments even the same type of internally stressed isolation material may result in superior transistor performance of P-channel transistors and N-channel transistors. | 07-18-2013 |
20130196495 | METHODS FOR FABRICATING MOS DEVICES WITH STRESS MEMORIZATION - A MOS device and methods for its fabrication are provided. In one embodiment the MOS device is fabricated on and within a semiconductor substrate. The method includes forming a gate structure having a top and sidewalls and having a gate insulator overlying the semiconductor substrate, a gate electrode overlying the gate insulator, and a cap overlying the gate electrode. An oxide liner is deposited over the top and sidewalls of the gate structure. In the method, the cap is etched from the gate structure and oxide needles extending upward from the gate structure are exposed. A stress-inducing layer is deposited over the oxide needles and gate structure and the semiconductor substrate is annealed. Then, the stress-inducing liner is removed. | 08-01-2013 |
20130244437 | METHODS OF FORMING FEATURES ON AN INTEGRATED CIRCUIT PRODUCT USING A NOVEL COMPOUND SIDEWALL IMAGE TRANSFER TECHNIQUE - One illustrative method disclosed herein includes forming a sacrificial mandrel above a structure, forming a plurality of first sidewall spacers on opposite sides of the sacrificial mandrel, removing the sacrificial mandrel, forming a plurality of second sidewall spacers on opposite sides of each of the first sidewall spacers, and removing the first sidewall spacers to thereby define a patterned spacer mask layer comprised of the plurality of second sidewall spacers. | 09-19-2013 |
20130277746 | INTEGRATED CIRCUITS HAVING PROTRUDING SOURCE AND DRAIN REGIONS AND METHODS FOR FORMING INTEGRATED CIRCUITS - Methods for forming integrated circuits and integrated circuits are disclosed. The integrated circuits comprise gate structures overlying and transverse to one or more fins that are delineated by trenches formed in a semiconductor substrate. Protruding portions are formed in the trenches in between the gate electrode structure on exposed sidewall surfaces of the one or more fins. The trenches are filled with an insulating material between the protruding portions and the gate structures. | 10-24-2013 |
20130341722 | ULTRATHIN BODY FULLY DEPLETED SILICON-ON-INSULATOR INTEGRATED CIRCUITS AND METHODS FOR FABRICATING SAME - Integrated circuits and methods for fabricating integrated circuits are provided. In an embodiment, a method for fabricating an integrated circuit includes providing an ultrathin body (UTB) fully depleted silicon-on-insulator (FDSOI) substrate. A PFET temporary gate structure and an NFET temporary gate structure are formed on the substrate. The method implants ions to form lightly doped active areas around the gate structures. A diffusionless annealing process is performed on the active areas. Further, a compressive strain region is formed around the PFET gate structure and a tensile strain region is formed around the NFET gate structure. | 12-26-2013 |
20140015055 | FINFET STRUCTURES AND METHODS FOR FABRICATING THE SAME - A method is disclosed for fabricating an integrated circuit in a replacement-gate process flow utilizing a dummy-gate structure overlying a plurality of fin structures. The method includes removing the dummy-gate structure to form a first void space, depositing a shaper material to fill the first void space, removing a portion of the plurality of fin structures to form a second void space, epitaxially growing a high carrier mobility material to fill the second void space, removing the shaper material to form a third void space, and depositing a replacement metal gate material to fill the third void space. | 01-16-2014 |
20140027825 | THRESHOLD VOLTAGE ADJUSTMENT IN A FIN TRANSISTOR BY CORNER IMPLANTATION - When forming sophisticated multiple gate transistors and planar transistors in a common manufacturing sequence, the threshold voltage characteristics of the multiple gate transistors may be intentionally “degraded” by selectively incorporating a dopant species into corner areas of the semiconductor fins, thereby obtaining a superior adaptation of the threshold voltage characteristics of multiple gate transistors and planar transistors. In advantageous embodiments, the incorporation of the dopant species may be accomplished by using the hard mask, which is also used for patterning the self-aligned semiconductor fins. | 01-30-2014 |
20140030876 | METHODS FOR FABRICATING HIGH CARRIER MOBILITY FINFET STRUCTURES - A method for fabricating an integrated circuit having a FinFET structure includes providing a semiconductor substrate comprising silicon and a high carrier mobility material, forming one or more fin structures on the semiconductor substrate, and subjecting the substrate to a condensation process for the condensation of the high carrier mobility material. The condensation process results in the formation of condensed fin structures formed substantially entirely of the high carrier mobility material and a layer of silicon oxide formed over the condensed fin structures. The method further includes removing the silicon oxide formed over the condensed fin structures so as to expose the condensed fin structures. | 01-30-2014 |
20140117418 | THREE-DIMENSIONAL SILICON-BASED TRANSISTOR COMPRISING A HIGH-MOBILITY CHANNEL FORMED BY NON-MASKED EPITAXY - Three-dimensional transistors may be formed on the basis of high mobility semiconductor materials, which may be provided locally restricted in the channel region by selective epitaxial growth processes without using a mask material for laterally confining the growing of the high mobility semiconductor material. That is, by controlling process parameters of the selective epitaxial growth process, the cross-sectional shape may be adjusted without requiring a mask material, thereby reducing overall process complexity and providing an additional degree of freedom for adjusting the transistor characteristics in terms of threshold voltage, drive current and electrostatic control of the channel region. | 05-01-2014 |
20140131735 | SOURCE AND DRAIN DOPING USING DOPED RAISED SOURCE AND DRAIN REGIONS - A method comprises providing a semiconductor structure comprising a substrate, an electrically insulating layer on the substrate and a semiconductor feature on the electrically insulating layer. A gate structure is formed on the semiconductor feature. An in situ doped semiconductor material is deposited on portions of the semiconductor feature adjacent the gate structure. Dopant is diffused from the in situ doped semiconductor material into the portions of the semiconductor feature adjacent the gate structure, the diffusion of the dopant into the portions of the semiconductor feature adjacent the gate structure forming doped source and drain regions in the semiconductor feature. | 05-15-2014 |
20140206157 | METHOD OF FORMING A SEMICONDUCTOR STRUCTURE INCLUDING A VERTICAL NANOWIRE - A method comprises providing a semiconductor structure comprising a substrate and a nanowire above the substrate. The nanowire comprises a first semiconductor material and extends in a vertical direction of the substrate. A material layer is formed above the substrate. The material layer annularly encloses the nanowire. A first part of the nanowire is selectively removed relative to the material layer. A second part of the nanowire is not removed. A distal end of the second part of the nanowire distal from the substrate is closer to the substrate than a surface of the material layer so that the semiconductor structure has a recess at the location of the nanowire. The distal end of the nanowire is exposed at the bottom of the recess. The recess is filled with a second semiconductor material. The second semiconductor material is differently doped than the first semiconductor material. | 07-24-2014 |
20140246696 | TRANSISTOR WITH EMBEDDED STRAIN-INDUCING MATERIAL FORMED IN CAVITIES FORMED IN A SILICON/GERMANIUM SUBSTRATE - When forming sophisticated semiconductor devices including N-channel transistors with strain-inducing embedded source and drain semiconductor regions, N-channel transistor performance may be enhanced by selectively growing embedded pure silicon source and drain regions in cavities exposing the silicon/germanium layer of a Si/SiGe-substrate, wherein the silicon layer of the Si/SiGe-substrate may exhibit a strong bi-axial tensile strain. The bi-axial tensile strain may improve both electron and hole mobility. | 09-04-2014 |
20140361335 | DEVICE INCLUDING A TRANSISTOR HAVING A STRESSED CHANNEL REGION AND METHOD FOR THE FORMATION THEREOF - A device includes a substrate, a P-channel transistor and an N-channel transistor. The substrate includes a first layer of a first semiconductor material and a second layer of a second semiconductor material. The first and second semiconductor materials have different crystal lattice constants. The P-channel transistor includes a channel region having a compressive stress in a first portion of the substrate. The channel region of the P-channel transistor includes a portion of the first layer of the first semiconductor material and a portion of the second layer of the second semiconductor material. The N-channel transistor includes a channel region having a tensile stress formed in a second portion of the substrate. The channel region of the N-channel transistor includes a portion of the first layer of the first semiconductor material and a portion of the second layer of the second semiconductor material. Methods of forming the device are also disclosed. | 12-11-2014 |