| Patent application number | Description | Published |
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| 20110147809 | FORMING A CARBON CONTAINING LAYER TO FACILITATE SILICIDE STABILITY IN A SILICON GERMANIUM MATERIAL - A method includes forming a silicon germanium layer, forming a layer comprising carbon and silicon on a top surface of the silicon germanium layer, forming a metal layer above the layer comprising carbon and silicon, and performing a thermal treatment to convert at least the layer comprising carbon and silicon to form a metal silicide layer. | 06-23-2011 |
| 20110227156 | SOI Schottky Source/Drain Device Structure to Control Encroachment and Delamination of Silicide - A Schottky field effect transistor is provided that includes a substrate having a layer of semiconductor material atop a dielectric layer, wherein the layer of semiconductor material has a thickness of less than 10.0 nm. A gate structure is present on the layer of semiconductor material. Raised source and drain regions comprised of a metal semiconductor alloy are present on the layer of semiconductor material on opposing sides of the gate structure. The raised source and drain regions are Schottky source and drain regions. In one embodiment, a first portion of the Schottky source and drain regions that is adjacent to a channel region of the Schottky field effect transistor contacts the dielectric layer, and a non-reacted semiconductor material is present between a second portion of the Schottky source and drain regions and the dielectric layer. | 09-22-2011 |
| 20110230017 | Method for Forming an SOI Schottky Source/Drain Device to Control Encroachment and Delamination of Silicide - A method of fabricating a Schottky field effect transistor is provided that includes providing a substrate having at least a first semiconductor layer overlying a dielectric layer, wherein the first semiconductor layer has a thickness of less than 10.0 nm. A gate structure is formed directly on the first semiconductor layer. A raised semiconductor material is selectively formed on the first semiconductor layer adjacent to the gate structure. The raised semiconductor material is converted into Schottky source and drain regions composed of a metal semiconductor alloy. A non-reacted semiconductor material is present between the Schottky source and drain regions and the dielectric layer. | 09-22-2011 |
| 20110241213 | Silicide Contact Formation - A method for forming a silicide contact includes depositing a metal layer on silicon such that the metal layer intermixes with the silicon to form an intermixed region on the silicon; removing an unintermixed portion of the metal layer from the intermixed region; and annealing the intermixed region to form a silicide contact on the silicon. A semiconductor device comprising a silicide contact located over a silicon layer of the semiconductor device, the silicide contact comprising nickel (Ni) and silicon (Si) and having Ni amount equivalent to a thickness of about 21 angstroms or less. | 10-06-2011 |
| 20110260252 | USE OF EPITAXIAL NI SILICIDE - An epitaxial Ni silicide film that is substantially non-agglomerated at high temperatures, and a method for forming the epitaxial Ni silicide film, is provided. The Ni silicide film of the present disclosure is especially useful in the formation of ETSOI (extremely thin silicon-on-insulator) Schottky junction source/drain FETs. The resulting epitaxial Ni silicide film exhibits improved thermal stability and does not agglomerate at high temperatures. | 10-27-2011 |
| 20120098042 | SEMICONDUCTOR DEVICE WITH REDUCED JUNCTION LEAKAGE AND AN ASSOCIATED METHOD OF FORMING SUCH A SEMICONDUCTOR DEVICE - Disclosed is a semiconductor device having a p-n junction with reduced junction leakage in the presence of metal silicide defects that extend to the junction and a method of forming the device. Specifically, a semiconductor layer having a p-n junction is formed. A metal silicide layer is formed on the semiconductor layer and a dopant is implanted into the metal silicide layer. An anneal process is performed causing the dopant to migrate toward the metal silicide-semiconductor layer interface such that the peak concentration of the dopant will be within a portion of the metal silicide layer bordering the metal silicide-semiconductor layer interface and encompassing the defects. As a result, the silicide to silicon contact is effectively engineered to increase the Schottky barrier height at the defect, which in turn drastically reduces any leakage that would otherwise occur, when the p-n junction is in reverse polarity. | 04-26-2012 |
| 20120112292 | INTERMIXED SILICIDE FOR REDUCTION OF EXTERNAL RESISTANCE IN INTEGRATED CIRCUIT DEVICES - A method for forming an alternate conductive path in semiconductor devices includes forming a silicided contact in a source/drain region adjacent to an extension diffusion region and removing sidewall spacers from a gate structure. A metal layer is formed over a portion of the extension diffusion region in a substrate layer to intermix metal from the metal layer with the portion of the extension region without annealing the metal layer. An unmixed portion of the metal layer is removed. The alternate conductive path is formed on the extension diffusion region with intermixed metal by thermal processing after the unmixed portion of the metal layer has been removed. | 05-10-2012 |
| 20120132989 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 05-31-2012 |
| 20120181697 | METHOD TO CONTROL METAL SEMICONDUCTOR MICRO-STRUCTURE - A method of forming a metal semiconductor alloy that includes forming an intermixed metal semiconductor region to a first depth of a semiconductor substrate without thermal diffusion. The intermixed metal semiconductor region is annealed to form a textured metal semiconductor alloy. A second metal layer is formed on the textured metal semiconductor alloy. The second metal layer on the textured metal semiconductor alloy is then annealed to form a metal semiconductor alloy contact, in which metal elements from the second metal layer are diffused through the textured metal semiconductor alloy to provide a templated metal semiconductor alloy. The templated metal semiconductor alloy includes a grain size that is greater than 2× for the metal semiconductor alloy, which has a thickness ranging from 15 nm to 50 nm. | 07-19-2012 |
| 20120190192 | Metal-Semiconductor Intermixed Regions - In one exemplary embodiment, a program storage device readable by a machine, tangibly embodying a program of instructions executable by the machine for performing operations, said operations including: depositing a first layer having a first metal on a surface of a semiconductor structure, where depositing the first layer creates a first intermix region at an interface of the first layer and the semiconductor structure; removing a portion of the deposited first layer to expose the first intermix region; depositing a second layer having a second metal on the first intermix region, where depositing the second layer creates a second intermix region at an interface of the second layer and the first intermix region; removing a portion of the deposited second layer to expose the second intermix region; and performing at least one anneal on the semiconductor structure. | 07-26-2012 |
| 20120295439 | Metal-Semiconductor Intermixed Regions - In one exemplary embodiment, a program storage device readable by a machine, tangibly embodying a program of instructions executable by the machine for performing operations, said operations including: depositing a first layer having a first metal on a surface of a semiconductor structure, where depositing the first layer creates a first intermix region at an interface of the first layer and the semiconductor structure; removing a portion of the deposited first layer to expose the first intermix region; depositing a second layer having a second metal on the first intermix region, where depositing the second layer creates a second intermix region at an interface of the second layer and the first intermix region; removing a portion of the deposited second layer to expose the second intermix region; and performing at least one anneal on the semiconductor structure. | 11-22-2012 |
| 20120298965 | MULTIGATE STRUCTURE FORMED WITH ELECTROLESS METAL DEPOSITION - A multigate structure which comprises a semiconductor substrate; an ultra-thin silicon or carbon bodies of less than 20 nanometers thick located on the substrate; an electrolessly deposited metallic layer selectively located on the side surfaces and top surfaces of the ultra-thin silicon or carbon bodies and selectively located on top of the multigate structures to make electrical contact with the ultra-thin silicon or carbon bodies and to minimize parasitic resistance, and wherein the ultra-thin silicon or carbon bodies and metallic layer located thereon form source and drain regions is provided along with a process to fabricate the structure. | 11-29-2012 |
| 20130012020 | USE OF EPITAXIAL NI SILICIDE - An epitaxial Ni silicide film that is substantially non-agglomerated at high temperatures, and a method for forming the epitaxial Ni silicide film, is provided. The Ni silicide film of the present disclosure is especially useful in the formation of ETSOI (extremely thin silicon-on-insulator) Schottky junction source/drain FETs. The resulting epitaxial Ni silicide film exhibits improved thermal stability and does not agglomerate at high temperatures. | 01-10-2013 |
| 20130241007 | USE OF BAND EDGE GATE METALS AS SOURCE DRAIN CONTACTS - A method includes providing a semiconductor substrate having intentionally doped surface regions, the intentionally doped surface regions corresponding to locations of a source and a drain of a transistor; depositing a layer a band edge gate metal onto a gate insulator layer in a gate region of the transistor while simultaneously depositing the band edge gate metal onto the surface of the semiconductor substrate to be in contact with the intentionally doped surface regions; and depositing a layer of contact metal over the band edge gate metal in the gate region and in the locations of the source and the drain. The band edge gate metal in the source/drain regions reduces a Schottky barrier height of source/drain contacts of the transistor and serves to reduce contact resistance. A transistor fabricated in accordance with the method is also described. | 09-19-2013 |
| 20130241008 | Use of Band Edge Gate Metals as Source Drain Contacts - A device includes a gate stack formed over a channel in a semiconductor substrate. The gate stack includes a layer of gate insulator material, a layer of gate metal overlying the layer of gate insulator material, and a layer of contact metal overlying the layer band edge gate metal. The device further includes source and drain contacts adjacent to the channel. The source and drain contacts each include a layer of the gate metal that overlies and is in direct electrical contact with a doped region of the semiconductor substrate, and a layer of contact metal that overlies the layer of gate metal. | 09-19-2013 |
| 20130267090 | METHOD TO CONTROL METAL SEMICONDUCTOR MICRO-STRUCTURE - A method of forming a metal semiconductor alloy that includes forming an intermixed metal semiconductor region to a first depth of a semiconductor substrate without thermal diffusion. The intermixed metal semiconductor region is annealed to form a textured metal semiconductor alloy. A second metal layer is formed on the textured metal semiconductor alloy. The second metal layer on the textured metal semiconductor alloy is then annealed to form a metal semiconductor alloy contact, in which metal elements from the second metal layer are diffused through the textured metal semiconductor alloy to provide a templated metal semiconductor alloy. The templated metal semiconductor alloy includes a grain size that is greater than 2× for the metal semiconductor alloy, which has a thickness ranging from 15 nm to 50 nm. | 10-10-2013 |
