Patent application number | Description | Published |
20080237660 | METHOD TO DEPOSIT SILICON FILM ON A SUBSTRATE - A semiconductor device and a method to fabricate a semiconductor device on a silicon substrate are illustrated. The semiconductor may comprise an amorphous silicon film, in the source/drain region of a semiconductor, having low amount of hydrogen and high concentration of carbon and phosphorous, which enhances performance of the semiconductor device. | 10-02-2008 |
20080242037 | Semiconductor device having self-aligned epitaxial source and drain extensions - A method of forming a transistor with self-aligned source and drain extensions in close proximity to a gate dielectric layer of the transistor comprises forming a gate stack on a substrate, implanting a dopant into regions of the substrate adjacent to the gate stack, wherein the dopant increases the etch rate of the substrate and defines the location of the source and drain extensions, forming a pair of spacers on laterally opposite sides of the gate stack that are disposed atop the doped regions of the substrate, etching the doped regions of the substrate and portions of the substrate subjacent to the doped regions, wherein an etch rate of the doped regions is higher than an etch rate of the portions of the substrate subjacent to the doped regions, and depositing a silicon-based material in the etched portions of the substrate. | 10-02-2008 |
20090039390 | CMOS TRANSISTOR JUNCTION REGIONS FORMED BY A CVD ETCHING AND DEPOSITION SEQUENCE - This invention adds to the art of replacement source-drain cMOS transistors. Processes may involve etching a recess in the substrate material using one equipment set, then performing deposition in another. Disclosed is a method to perform the etch and subsequent deposition in the same reactor without atmospheric exposure. In-situ etching of the source-drain recess for replacement source-drain applications provides several advantages over state of the art ex-situ etching. Transistor drive current is improved by: (1) Eliminating contamination of the silicon-epilayer interface when the as-etched surface is exposed to atmosphere and (2) Precise control over the shape of the etch recess. Deposition may be done by a variety of techniques including selective and non-selective methods. In the case of blanket deposition, a measure to avoid amorphous deposition in performance critical regions is also presented. | 02-12-2009 |
20090065808 | SEMICONDUCTOR TRANSISTOR HAVING A STRESSED CHANNEL - A process is described for manufacturing an improved PMOS semiconductor transistor. Recesses are etched into a layer of epitaxial silicon. Source and drain films are deposited in the recesses. The source and drain films are made of an alloy of silicon and germanium. The alloy is epitaxially deposited on the layer of silicon. The alloy thus has a lattice having the same structure as the structure of the lattice of the layer of silicon. However, due to the inclusion of the germanium, the lattice of the alloy has a larger spacing than the spacing of the lattice of the layer of silicon. The larger spacing creates a stress in a channel of the transistor between the source and drain films. The stress increases I | 03-12-2009 |
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 |
20090152601 | Strained NMOS transistor featuring deep carbon doped regions and raised donor doped source and drain - Some embodiments of the present invention include providing carbon doped regions and raised source/drain regions to provide tensile stress in NMOS transistor channels. | 06-18-2009 |
20090315076 | TRANSISTOR GATE ELECTRODE HAVING CONDUCTOR MATERIAL LAYER - Various embodiments of the invention relate to a PMOS device having a transistor channel of silicon germanium material on a substrate, a gate dielectric having a dielectric constant greater than that of silicon dioxide on the channel, a gate electrode conductor material having a work function in a range between a valence energy band edge and a conductor energy band edge for silicon on the gate dielectric, and a gate electrode semiconductor material on the gate electrode conductor material. | 12-24-2009 |
20090321838 | CMOS DEVICE AND METHOD OF MANUFACTURING SAME - A CMOS device includes NMOS ( | 12-31-2009 |
20100038685 | ENHANCED DISLOCATION STRESS TRANSISTOR - A device is provided. The device includes a transistor formed on a semiconductor substrate, the transistor having a conduction channel. The device includes at least one edge dislocation formed adjacent to the conduction channel on the semiconductor substrate. The device also includes at least one free surface introduced above the conduction channel and the at least one edge dislocation. | 02-18-2010 |
20100044754 | STRAINED TRANSISTOR INTEGRATION FOR CMOS - Various embodiments of the invention relate to a CMOS device having (1) an NMOS channel of silicon material selectively deposited on a first area of a graded silicon germanium substrate such that the selectively deposited silicon material experiences a tensile strain caused by the lattice spacing of the silicon material being smaller than the lattice spacing of the graded silicon germanium substrate material at the first area, and (2) a PMOS channel of silicon germanium material selectively deposited on a second area of the substrate such that the selectively deposited silicon germanium material experiences a compressive strain caused by the lattice spacing of the selectively deposited silicon germanium material being larger than the lattice spacing of the graded silicon germanium substrate material at the second area. | 02-25-2010 |
20100102356 | Semiconductor transistor having a stressed channel - A process is described for manufacturing an improved PMOS semiconductor transistor. Recesses are etched into a layer of epitaxial silicon. Source and drain films are deposited in the recesses. The source and drain films are made of an alloy of silicon and germanium. The alloy is epitaxially deposited on the layer of silicon. The alloy thus has a lattice having the same structure as the structure of the lattice of the layer of silicon. However, due to the inclusion of the germanium, the lattice of the alloy has a larger spacing than the spacing of the lattice of the layer of silicon. The larger spacing creates a stress in a channel of the transistor between the source and drain films. The stress increases I | 04-29-2010 |
20100102401 | Semiconductor transistor having a stressed channel - A process is described for manufacturing an improved PMOS semiconductor transistor. Recesses are etched into a layer of epitaxial silicon. Source and drain films are deposited in the recesses. The source and drain films are made of an alloy of silicon and germanium. The alloy is epitaxially deposited on the layer of silicon. The alloy thus has a lattice having the same structure as the structure of the lattice of the layer of silicon. However, due to the inclusion of the germanium, the lattice of the alloy has a larger spacing than the spacing of the lattice of the layer of silicon. The larger spacing creates a stress in a channel of the transistor between the source and drain films. The stress increases IDSAT and I | 04-29-2010 |
20100109046 | Methods of forming low interface resistance contacts and structures formed thereby - Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a tapered contact opening in an ILD disposed on a substrate, wherein a source/drain contact area is exposed, preamorphizing a portion of a source drain region of the substrate, implanting boron into the source/drain region through the tapered contact opening, forming a metal layer on the source/drain contact area, and then annealing the metal layer to form a metal silicide. | 05-06-2010 |
20100148217 | Graded high germanium compound films for strained semiconductor devices - Embodiments of an apparatus and methods for providing a graded high germanium compound region are generally described herein. Other embodiments may be described and claimed. | 06-17-2010 |
20110006344 | Method for improving transistor performance through reducing the salicide interface resistance - An embodiment of the invention reduces the external resistance of a transistor by utilizing a silicon germanium alloy for the source and drain regions and a nickel silicon germanium self-aligned silicide (i.e., salicide) layer to form the contact surface of the source and drain regions. The interface of the silicon germanium and the nickel silicon germanium silicide has a lower specific contact resistivity based on a decreased metal-semiconductor work function between the silicon germanium and the silicide and the increased carrier mobility in silicon germanium versus silicon. The silicon germanium may be doped to further tune its electrical properties. A reduction of the external resistance of a transistor equates to increased transistor performance both in switching speed and power consumption. | 01-13-2011 |
20110018031 | TRANSISTOR GATE ELECTRODE HAVING CONDUCTOR MATERIAL LAYER - Various embodiments of the invention relate to a PMOS device having a transistor channel of silicon germanium material on a substrate, a gate dielectric having a dielectric constant greater than that of silicon dioxide on the channel, a gate electrode conductor material having a work function in a range between a valence energy band edge and a conductor energy band edge for silicon on the gate dielectric, and a gate electrode semiconductor material on the gate electrode conductor material. | 01-27-2011 |
20110068403 | STRAINED NMOS TRANSISTOR FEATURING DEEP CARBON DOPED REGIONS AND RAISED DONOR DOPED SOURCE AND DRAIN - Some embodiments of the present invention include providing carbon doped regions and raised source/drain regions to provide tensile stress in NMOS transistor channels. | 03-24-2011 |
20110101418 | Method for improving transistor performance through reducing the salicide interface resistance - An embodiment of the invention reduces the external resistance of a transistor by utilizing a silicon germanium alloy for the source and drain regions and a nickel silicon germanium self-aligned silicide (i.e., salicide) layer to form the contact surface of the source and drain regions. The interface of the silicon germanium and the nickel silicon germanium silicide has a lower specific contact resistivity based on a decreased metal-semiconductor work function between the silicon germanium and the silicide and the increased carrier mobility in silicon germanium versus silicon. The silicon germanium may be doped to further tune its electrical properties. A reduction of the external resistance of a transistor equates to increased transistor performance both in switching speed and power consumption. | 05-05-2011 |
20110186912 | TRANSISTOR GATE ELECTRODE HAVING CONDUCTOR MATERIAL LAYER - Various embodiments of the invention relate to a PMOS device having a transistor channel of silicon germanium material on a substrate, a gate dielectric having a dielectric constant greater than that of silicon dioxide on the channel, a gate electrode conductor material having a work function in a range between a valence energy band edge and a conductor energy band edge for silicon on the gate dielectric, and a gate electrode semiconductor material on the gate electrode conductor material. | 08-04-2011 |
20110215375 | MULTI-COMPONENT STRAIN-INDUCING SEMICONDUCTOR REGIONS - A multi-component strain-inducing semiconductor region is described. In an embodiment, formation of such a strain-inducing semiconductor region laterally adjacent to a crystalline substrate results in a uniaxial strain imparted to the crystalline substrate, providing a strained crystalline substrate. In one embodiment, the multi-component strain-inducing material region comprises a first portion and a second portion which are separated by an interface. In a specific embodiment, the concentration of charge-carrier dopant impurity atoms of the two portions are different from one another at the interface. | 09-08-2011 |
20120032265 | GRADED HIGH GERMANIUM COMPOUND FILMS FOR STRAINED SEMICONDUCTOR DEVICES - Embodiments of an apparatus and methods for providing a graded high germanium compound region are generally described herein. Other embodiments may be described and claimed. | 02-09-2012 |
20120068180 | METHODS OF FORMING LOW INTERFACE RESISTANCE CONTACTS AND STRUCTURES FORMED THEREBY - Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a tapered contact opening in an ILD disposed on a substrate, wherein a source/drain contact area is exposed, preamorphizing a portion of a source drain region of the substrate, implanting boron into the source/drain region through the tapered contact opening, forming a metal layer on the source/drain contact area, and then annealing the metal layer to form a metal silicide. | 03-22-2012 |
20130153965 | STRAINED TRANSISTOR INTEGRATION FOR CMOS - Various embodiments of the invention relate to a CMOS device having (1) an NMOS channel of silicon material selectively deposited on a first area of a graded silicon germanium substrate such that the selectively deposited silicon material experiences a tensile strain caused by the lattice spacing of the silicon material being smaller than the lattice spacing of the graded silicon germanium substrate material at the first area, and (2) a PMOS channel of silicon germanium material selectively deposited on a second area of the substrate such that the selectively deposited silicon germanium material experiences a compressive strain caused by the lattice spacing of the selectively deposited silicon germanium material being larger than the lattice spacing of the graded silicon germanium substrate material at the second area. | 06-20-2013 |
20130302961 | METHOD FOR IMPROVING TRANSISTOR PERFORMANCE THROUGH REDUCING THE SALICIDE INTERFACE RESISTANCE - An embodiment of the invention reduces the external resistance of a transistor by utilizing a silicon germanium alloy for the source and drain regions and a nickel silicon germanium self-aligned silicide (i.e., salicide) layer to form the contact surface of the source and drain regions. The interface of the silicon germanium and the nickel silicon germanium silicide has a lower specific contact resistivity based on a decreased metal-semiconductor work function between the silicon germanium and the silicide and the increased carrier mobility in silicon germanium versus silicon. The silicon germanium may be doped to further tune its electrical properties. A reduction of the external resistance of a transistor equates to increased transistor performance both in switching speed and power consumption. | 11-14-2013 |
20140264280 | NANOWIRE TRANSISTOR WITH UNDERLAYER ETCH STOPS - A nanowire device of the present description may be produced with the incorporation of at least one underlayer etch stop formed during the fabrication of at least one nanowire transistor in order to assist in protecting source structures and/or drain structures from damage that may result from fabrication processes. The underlayer etch stop may prevent damage to the source structures andor drain the structures, when the material used in the fabrication of the source structures andor the drain structures is susceptible to being etched by the processes used in the removal of the sacrificial materials, i.e. low selectively to the source structure and/or the drain structure materials, such that potential shorting between the transistor gate electrodes and contacts formed for the source structures andor the drain structures may be prevented. | 09-18-2014 |
20140284626 | ENHANCED DISLOCATION STRESS TRANSISTOR - A device is provided. The device includes a transistor formed on a semiconductor substrate, the transistor having a conduction channel. The device includes at least one edge dislocation formed adjacent to the conduction channel on the semiconductor substrate. The device also includes at least one free surface introduced above the conduction channel and the at least one edge dislocation. | 09-25-2014 |