Patent application number | Description | Published |
20100128260 | SEMICONDUCTOR NANOWIRE ELECTROMAGNETIC RADIATION SENSOR - A semiconductor nanowire is coated with a chemical coating layer that selectively attaches to the semiconductor material and which forms a dye in a chemical reaction. The dye layer comprises a material that absorbs electromagnetic radiation. A portion of the absorbed energy induces electronic excitation in the chemical coating layer from which additional free charge carriers are temporarily donated into the semiconductor nanowire. Thus, the conductivity of the semiconductor nanowire increases upon illumination on the dye layer. The semiconductor nanowire, and the resulting dye layer collective operate as a detector for electromagnetic radiation. | 05-27-2010 |
20100129925 | SEMICONDUCTOR NANOWIRES CHARGE SENSOR - A semiconductor nanowire is coated with a chemical coating layer that comprises a functional material which modulates the quantity of free charge carriers within the semiconductor nanowire. The outer surface of the chemical coating layer includes a chemical group that facilitates bonding with molecules to be detected through electrostatic forces. The bonding between the chemical coating layer and the molecules alters the electrical charge distribution in the chemical coating layer, which alters the amount of the free charge carriers and the conductivity in the semiconductor nanowire. The coated semiconductor nanowire may be employed as a chemical sensor for the type of chemicals that bonds with the functional material in the chemical coating layer. Detection of such chemicals may indicate pH of a solution, a vapor pressure of a reactive material in gas phase, and/or a concentration of a molecule in a solution. | 05-27-2010 |
20100252800 | NANOWIRE DEVICES FOR ENHANCING MOBILITY THROUGH STRESS ENGINEERING - A p-type semiconductor nanowire transistor is formed on the first semiconductor nanowire and an n-type semiconductor nanowire transistor is formed on the second semiconductor nanowire. The first and second semiconductor nanowires have a rectangular cross-sectional area with different width-to-height ratios. The type of semiconductor nanowires for each semiconductor nanowire transistor is selected such that top and bottom surfaces provide a greater on-current per unit width than sidewall surfaces in a semiconductor nanowire having a greater width-to-height ratio, while sidewall surfaces provide a greater on-current per unit width than top and bottom surfaces in the other semiconductor nanowire having a lesser width-to-height ratio. Different types of stress-generating material layers may be formed on the first and second semiconductor nanowire transistors to provide opposite types of stress, which may be employed to enhance the on-current of the first and second semiconductor nanowire transistors. | 10-07-2010 |
20100252801 | SEMICONDUCTOR NANOWIRE WITH BUILT-IN STRESS - A semiconductor nanowire having two semiconductor pads on both ends is suspended over a substrate. Stress-generating liner portions are formed over the two semiconductor pads, while a middle portion of the semiconductor nanowire is exposed. A gate dielectric and a gate electrode are formed over the middle portion of the semiconductor nanowire while the semiconductor nanowire is under longitudinal stress due to the stress-generating liner portions. The middle portion of the semiconductor nanowire is under a built-in inherent longitudinal stress after removal of the stress-generating liners because the formation of the gate dielectric and the gate electrode locks in the strained state of the semiconductor nanowire. Source and drain regions are formed in the semiconductor pads to provide a semiconductor nanowire transistor. A middle-of-line (MOL) dielectric layer may be formed directly on the source and drain pads. | 10-07-2010 |
20100252810 | GATE PATTERNING OF NANO-CHANNEL DEVICES - Methodologies and gate etching processes are presented to enable the fabrication of gate conductors of semiconductor devices, such as NFETs and/or PFETs, which are equipped with nano-channels. In one embodiment, a sacrificial spacer of equivalent thickness to the diameter of the gate nano-channel is employed and is deposited after patterning the gate conductor down to the gate dielectric. The residue gate material that is beneath the nano-channel is removed utilizing a medium to high density, bias-free, fluorine-containing or fluorine- and chlorine-containing isotropic etch process without compromising the integrity of the gate. In another embodiment, an encapsulation/passivation layer is utilized. In yet further embodiment, no sacrificial spacer or encapsulation/passivation layer is used and gate etching is performed in an oxygen and nitrogen-free ambient. | 10-07-2010 |
20100252814 | SEMICONDUCTOR NANOWIRES HAVING MOBILITY-OPTIMIZED ORIENTATIONS - Prototype semiconductor structures each including a semiconductor link portion and two adjoined pad portions are formed by lithographic patterning of a semiconductor layer on a dielectric material layer. The sidewalls of the semiconductor link portions are oriented to maximize hole mobility for a first-type semiconductor structures, and to maximize electron mobility for a second-type semiconductor structures. Thinning by oxidation of the semiconductor structures reduces the width of the semiconductor link portions at different rates for different crystallographic orientations. The widths of the semiconductor link portions are predetermined so that the different amount of thinning on the sidewalls of the semiconductor link portions result in target sublithographic dimensions for the resulting semiconductor nanowires after thinning. By compensating for different thinning rates for different crystallographic surfaces, semiconductor nanowires having optimal sublithographic widths may be formed for different crystallographic orientations without excessive thinning or insufficient thinning. | 10-07-2010 |
20100252815 | STRUCTURALLY STABILIZED SEMICONDUCTOR NANOWIRE - In one embodiment, a semiconductor nanowire having a monotonically increasing width with distance from a middle portion toward adjoining semiconductor pads is provided. A semiconductor link portion having tapered end portions is lithographically patterned. During the thinning process that forms a semiconductor nanowire, the taper at the end portions of the semiconductor nanowire provides enhanced mechanical strength to prevent structural buckling or bending. In another embodiment, a semiconductor nanowire having bulge portions are formed by preventing the thinning of a semiconductor link portion at pre-selected positions. The bulge portions having a greater width than a middle portion of the semiconductor nanowire provides enhanced mechanical strength during thinning of the semiconductor link portion so that structural damage to the semiconductor nanowire is avoided during thinning. | 10-07-2010 |
20100295020 | Method For Forming A Robust Top-Down Silicon Nanowire Structure Using A Conformal Nitride And Such Structure - A nanowire product and process for fabricating it has a wafer with a buried oxide (BOX) upper layer in which a well is formed and the ends of a nanowire are on the BOX layer forming a beam that spans the well. A mask coating is formed on the upper surface of the BOX layer leaving an uncoated window over a center part of the beam and also forming a mask coating around the beam intermediate ends between each end of the beam center part and a side wall of the well. Applying oxygen through the window thins the beam center part while leaving the wire intermediate ends over the well thicker and having a generally arched shape. A thermal oxide coating can be placed on the wire and also the mask on the BOX layer before oxidation. | 11-25-2010 |
20110006367 | GATE PATTERNING OF NANO-CHANNEL DEVICES - Methodologies and gate etching processes are presented to enable the fabrication of gate conductors of semiconductor devices, such as NFETs and/or PFETs, which are equipped with nano-channels. In one embodiment, a sacrificial spacer of equivalent thickness to the diameter of the gate nano-channel is employed and is deposited after patterning the gate conductor down to the gate dielectric. The residue gate material that is beneath the nano-channel is removed utilizing a medium to high density, bias-free, fluorine-containing or fluorine- and chlorine-containing isotropic etch process without compromising the integrity of the gate. In another embodiment, an encapsulation/passivation layer is utilized. In yet further embodiment, no sacrificial spacer or encapsulation/passivation layer is used and gate etching is performed in an oxygen and nitrogen-free ambient. | 01-13-2011 |
20110012176 | Multiple Orientation Nanowires With Gate Stack Stressors - An electronic device includes a conductive channel defining a crystal structure and having a length and a thickness t | 01-20-2011 |
20110012177 | Nanostructure For Changing Electric Mobility - A structure and a method for a semiconductor including a nanostructure semiconductor channel. The semiconductor may include a dielectric and an electrode, the electrode attached to the dielectric, a semiconductor channel may be disposed proximate to the dielectric, wherein the semiconductor channel has an electric mobility and is configured to have at least one dimension, and wherein the dielectric may be configured to apply a force at the at least one dimension. | 01-20-2011 |
20110104860 | SEMICONDUCTOR NANOWIRE WITH BUILT-IN STRESS - A semiconductor nanowire having two semiconductor pads on both ends is suspended over a substrate. Stress-generating liner portions are formed over the two semiconductor pads, while a middle portion of the semiconductor nanowire is exposed. A gate dielectric and a gate electrode are formed over the middle portion of the semiconductor nanowire while the semiconductor nanowire is under longitudinal stress due to the stress-generating liner portions. The middle portion of the semiconductor nanowire is under a built-in inherent longitudinal stress after removal of the stress-generating liners because the formation of the gate dielectric and the gate electrode locks in the strained state of the semiconductor nanowire. Source and drain regions are formed in the semiconductor pads to provide a semiconductor nanowire transistor. A middle-of-line (MOL) dielectric layer may be formed directly on the source and drain pads. | 05-05-2011 |
20110124187 | VAPOR PHASE DEPOSITION PROCESSES FOR DOPING SILICON - A process of doping a silicon layer with dopant atoms generally includes reacting a vapor of a dopant precursor with oxide and/or hydroxide reactive sites present on the silicon layer to form a self assembled monolayer of dopant precursor; hydrolyzing the self assembled monolayer of the dopant precursor with water vapor to form pendant hydroxyl groups on the dopant precursor; capping the self assembled monolayer with an oxide layer; and annealing the silicon layer at a temperature effective to diffuse dopant atoms from the dopant precursor into the silicon layer. Additional monolayers can be formed in a similar manner, thereby providing controlled layer-by-layer vapor phase deposition of the dopant precursor compounds for controlled doping of silicon. | 05-26-2011 |
20110175063 | SEMICONDUCTOR NANOWIRES HAVING MOBILITY-OPTIMIZED ORIENTATIONS - Prototype semiconductor structures each including a semiconductor link portion and two adjoined pad portions are formed by lithographic patterning of a semiconductor layer on a dielectric material layer. The sidewalls of the semiconductor link portions are oriented to maximize hole mobility for a first-type semiconductor structures, and to maximize electron mobility for a second-type semiconductor structures. Thinning by oxidation of the semiconductor structures reduces the width of the semiconductor link portions at different rates for different crystallographic orientations. The widths of the semiconductor link portions are predetermined so that the different amount of thinning on the sidewalls of the semiconductor link portions result in target sublithographic dimensions for the resulting semiconductor nanowires after thinning. By compensating for different thinning rates for different crystallographic surfaces, semiconductor nanowires having optimal sublithographic widths may be formed for different crystallographic orientations without excessive thinning or insufficient thinning. | 07-21-2011 |
20110223751 | DOPING OF SEMICONDUCTOR SUBSTRATE THROUGH CARBONLESS PHOSPHOROUS-CONTAINING LAYER - A method and system are disclosed for doping a semiconductor substrate. In one embodiment, the method comprises forming a carbon free layer of phosphoric acid on a semiconductor substrate, and diffusing phosphorous from the layer of phosphoric acid in the substrate to form an activated phosphorous dopant therein. In an embodiment, the semiconductor substrate is immersed in a solution of a phosphorous compound to form a layer of the phosphorous compound on the substrate, and this layer of phosphorous is processed to form the layer of phosphoric acid. In an embodiment, this processing may include hydrolyzing the layer of the phosphorous compound to form the layer of phosphoric acid. In one embodiment, an oxide cap layer is formed on the phosphoric acid layer to form a capped substrate. The capped substrate may be annealed to diffuse the phosphorous in the substrate and to form the activated dopant. | 09-15-2011 |
20120322215 | COMMUNICATION - An electronic device includes a conductive channel defining a crystal structure and having a length and a thickness t | 12-20-2012 |
20130015507 | MULTIPLE ORIENTATION NANOWIRES WITH GATE STACK SENSORS - An electronic device includes a conductive channel defining a crystal structure and having a length and a thickness t | 01-17-2013 |