Abstract: The present invention discloses a novel ferroelectric transistor design using a resistive oxide film in place of the gate dielectric. By replacing the gate dielectric with a resistive oxide film, and by optimizing the value of the film resistance, the bottom gate of the ferroelectric layer is electrically connected to the silicon substrate, eliminating the trapped charge effect and resulting in the improvement of the memory retention characteristics. The resistive oxide film is preferably a doped conductive oxide in which a conductive oxide is doped with an impurity species. The doped conductive oxide is most preferred to be In2O3 with the dopant species being hafnium oxide, zirconium oxide, lanthanum oxide, or aluminum oxide.

Abstract: A Pr1-XCaXMnO3 (PCMO) spin-coat deposition method for eliminating voids is provided, along with a void-free PCMO film structure. The method comprises: forming a substrate, including a noble metal, with a surface; forming a feature, such as a via or trench, normal with respect to the substrate surface; spin-coating the substrate with acetic acid; spin-coating the substrate with a first, low concentration of PCMO solution; spin-coating the substrate with a second concentration of PCMO solution, having a greater concentration of PCMO than the first concentration; baking and RTA annealing (repeated one to five times); post-annealing; and, forming a PCMO film with a void-free interface between the PCMO film and the underlying substrate surface. The first concentration of PCMO solution has a PCMO concentration in the range of 0.01 to 0.1 moles (M). The second concentration of PCMO solution has a PCMO concentration in the range of 0.2 to 0.5 M.

Abstract: A method is provided for forming iridium oxide (IrOx) nanotubes. The method comprises: providing a substrate; introducing a (methylcyclopentadienyl)(1,5-cyclooctadiene)iridium(I) precursor; introducing oxygen as a precursor reaction gas; establishing a final pressure in the range of 1 to 50 Torr; establishing a substrate, or chamber temperature in the range of 200 to 500 degrees C.; and using a metalorganic chemical vapor deposition (MOCVD) process, growing IrOx hollow nanotubes from the substrate surface. Typically, the (methylcyclopentadienyl)(1,5-cyclooctadiene)iridium(I) precursor is initially heated in an ampule to a first temperature in the range of 60 to 90 degrees C., and the first temperature is maintained in the transport line introducing the precursor. The precursor may be mixed with an inert carrier gas such as Ar, or the oxygen precursor reaction gas may be used as the carrier.

Abstract: A method of forming a tungsten nitride thin film in an integrated circuit includes preparing a silicon substrate on a silicon wafer and placing the silicon wafer in a heatable chuck in a CVD vacuum chamber; placing a known quantity of a tungsten source in a variable-temperature bubbler to provide a gaseous tungsten source; setting the variable-temperature bubbler to a predetermined temperature; passing a carrier gas through the variable-temperature bubbler and carrying the gaseous tungsten source with the carrier gas into the CVD vacuum chamber; introducing a nitrogen-containing reactant gas into the CVD vacuum chamber; reacting the gaseous tungsten source and the nitrogen-containing reactant gas above the surface of the silicon wafer in a deposition process to deposit a WxNy thin film on the surface of the silicon wafer; and completing the integrated circuit containing the WxNy thin film.

Abstract: Using programmable resistance material for a matching resistor, a resistor trimming circuit is designed to reversibly trim a matching resistor to match a reference resistor. The programmable resistance materials such as metal-amorphous silicon metal materials, phase change materials or perovskite materials are typically used in resistive memory devices and have the ability to change the resistance reversibly and repeatable with applied electrical pulses. The present invention reversible resistor trimming circuit comprises a resistance bridge network of a matching resistor and a reference resistor to provide inputs to a comparator circuit which generates a comparing signal indicative of the resistance difference. This comparing signal can be used to control a feedback circuit to provide appropriate electrical pulses to the matching resistor to modify the resistance of the matching resistor to match that of the reference resistor.

Abstract: A method to fabricate a silicon-on-nothing device on a silicon substrate is provided. The disclosed silicon-on-nothing device is fabricated on an isolated floating silicon active area, thus completely isolated from the silicon substrate by an air gap. The isolated floating silicon active area is fabricated on a silicon germanium layer with a surrounding isolation trench. A plurality of anchors is then fabricated to anchor the silicon active area to the silicon substrate before selectively etching the silicon germanium layer to form the air gap. Isolation trench fill and planarization complete the formation of the isolated floating silicon active area. The silicon-on-nothing device on the isolated floating silicon active area can be polysilicon gate or metal gate and with or without raised source and drain regions.

Abstract: A method of fabricating a silicon integrated circuit on a glass substrate includes preparing a glass substrate; fabricating a silicon layer on the glass substrate; implanting ions into the active areas of the silicon layer; covering the silicon layer with a heat pad material; activating the ions in the silicon layer by annealing while maintaining the glass substrate at a temperature below that of the thermal stability of the glass substrate; removing the heat pad material; and completing the silicon integrated circuit.

Abstract: A method of forming a silicon-germanium layer on an insulator includes depositing a layer of silicon-germanium on a silicon substrate to form a silicon/silicon-germanium portion; implanting hydrogen ions into the silicon substrate between about 500 ? to 1 ?m below a silicon-germanium/silicon interface; bonding the silicon/silicon-germanium portion to an insulator substrate to form a couplet; thermally annealing the couplet in a first thermal annealing step to split the couplet; patterning and etching the silicon-germanium-on-insulator portion to remove portions of the silicon and SiGe layers; etching the silicon-germanium-on-insulator portion to remove the remaining silicon layer; thermally annealing the silicon-germanium-on-insulator portion in a second annealing step to relaxed the SiGe layer; and depositing a layer of strained silicon about the SiGe layer.

Abstract: PrCaMnO (PCMO) thin films with predetermined memory-resistance characteristics and associated formation processes have been provided. In one aspect the method comprises: forming a Pr3+1?xCa2+xMnO thin film composition, where 0.1<x<0.6; in response to the selection of x, varying the ratio of Mn and O ions as follows: O2?(3±20%); Mn3+((1?x)±20%); and, Mn4+(x±20%). When the PCMO thin film has a Pr3+0.70Ca2+0.30Mn3+0.78Mn4+0.22O2?2.96 composition, the ratio of Mn and O ions varies as follows: O2?(2.96); Mn3+((1?x)+8%); and, Mn4+(x?8%). In another aspect, the method creates a density in the PCMO film, responsive to the crystallographic orientation. For example, if the PCMO film has a (110) orientation, a density is created in the range of 5 to 6.76 Mn atoms per 100 ?2 in a plane perpendicular to the (110) orientation.

Abstract: A method of selective etching a metal oxide layer for fabrication of a ferroelectric device includes preparing a silicon substrate, including forming an oxide layer thereon; depositing a layer of metal or metal oxide thin film on the substrate; patterning and selectively etching the metal or metal oxide thin film without substantially over etching into the underlying oxide layer; depositing a layer of ferroelectric material; depositing a top electrode on the ferroelectric material; and completing the ferroelectric device.

Abstract: A method is provided for patterning iridium oxide (IrOx) nanostructures. The method comprises: forming a substrate first region adjacent a second region; growing IrOx nanostructures from a continuous IrOx film overlying the first region; simultaneously growing IrOx nanostructures from a non-continuous IrOx film overlying the second region; selectively etching areas of the second region exposed by the non-continuous IrOx film; and, lifting off the IrOx nanostructures overlying the second region. Typically, the first region is formed from a first material and the second region from a second material, different than the first material. For example, the first material can be a refractory metal, or refractory metal oxide. The second material can be SiOx. The step of selectively etching areas of the second region exposed by the non-continuous IrOx film includes exposing the substrate to an etchant that is more reactive with the second material than the IrOx.

Abstract: Provided are a SiGe vertical optical path and a method for selectively forming a SiGe optical path normal structure for IR photodetection. The method comprises: forming a Si substrate surface; forming a Si feature, normal with respect to the Si substrate surface, such as a trench, via, or pillar; and, selectively forming a SiGe optical path overlying the Si normal feature. In some aspects, the Si substrate surface is formed a first plane and the Si normal feature has walls (sidewalls), normal with respect to the Si substrate surface, and a surface in a second plane, parallel to the first plane. Then, selectively forming a SiGe optical path overlying the Si normal feature includes forming a SiGe vertical optical path overlying the normal feature walls.

Abstract: Disclosing is a strained silicon finFET device having a strained silicon fin channel in a double gate finFET structure. The disclosed finFET device is a double gate MOSFET consisting of a silicon fin channel controlled by a self-aligned double gate for suppressing short channel effect and enhancing drive current. The silicon fin channel of the disclosed finFET device is a strained silicon fin channel, comprising a strained silicon layer deposited on a seed fin having different lattice constant, for example, a silicon layer deposited on a silicon germanium seed fin, or a carbon doped silicon layer deposited on a silicon seed fin. The lattice mismatch between the silicon layer and the seed fin generates the strained silicon fin channel in the disclosed finFET device to improve hole and electron mobility enhancement, in addition to short channel effect reduction characteristic inherently in a finFET device.

Abstract: A memory array dual-trench isolation structure and a method for forming the same have been provided.

Abstract: A method of etching a noble metal top electrode on a ferroelectric layer while preserving the ferroelectric properties of the ferroelectric layer and removing etching residue includes preparing a substrate; depositing a barrier layer on the substrate; depositing a bottom electrode layer on the barrier layer; depositing a ferroelectric layer on the bottom electrode layer; depositing a noble metal top electrode layer on the ferroelectric layer; depositing an adhesion layer on the top electrode layer; depositing a hard mask layer on the adhesion layer; patterning the hard mask; etching the noble metal top electrode layer in an initial etching step at a predetermined RF bias power, which produces etching residue; and over etching the noble metal top electrode layer and ferroelectric layer at an RF bias power lower than that of the predetermined RF bias power to remove etching residue from the initial etching step.

Abstract: A method of fabricating a germanium film on a silicon substrate includes preparing a silicon substrate; depositing a first germanium film to form a continuous germanium film on the silicon substrate; annealing the silicon substrate and the germanium film thereon in a first annealing process to relax the germanium film; depositing a second germanium film on the first germanium film to form a germanium layer; patterning and etching the germanium layer; depositing a layer of dielectric material on the germanium layer; cyclic annealing the silicon substrate having the germanium layer and dielectric material thereon; and completing a device containing the silicon substrate and germanium layer.

Abstract: A method of fabricating a doped-PCMO thin film layer includes preparing a PCMO precursor solution having a transition metal additive therein; and spin-coating the doped-PCMO spin-coating solution onto a wafer.

Abstract: A method is provided for forming a buffered-layer memory cell. The method comprises: forming a bottom electrode; forming a colossal magnetoresistance (CMR) memory film overlying the bottom electrode; forming a memory-stable semiconductor buffer layer, typically a metal oxide, overlying the memory film; and, forming a top electrode overlying the semiconductor buffer layer. In some aspects of the method the semiconductor buffer layer is formed from YBa2Cu3O7-X (YBCO), indium oxide (In2O3), or ruthenium oxide (RuO2), having a thickness in the range of 10 to 200 nanometers (nm). The top and bottom electrodes may be TiN/Ti, Pt/TiN/Ti, In/TiN/Ti, PtRhOx compounds, or PtIrOx compounds. The CMR memory film may be a Pr1-XCaXMnO3 (PCMO) memory film, where x is in the region between 0.1 and 0.6, with a thickness in the range of 10 to 200 nm.

Abstract: A method is provided for patterning iridium oxide (IrOx) nanostructures. The method comprises: forming a substrate first region adjacent a second region; growing IrOx nanostructures from a continuous IrOx film overlying the first region; simultaneously growing IrOx nanostructures from a non-continuous IrOx film overlying the second region; selectively etching areas of the second region exposed by the non-continuous IrOx film; and, lifting off the IrOx nanostructures overlying the second region. Typically, the first region is formed from a first material and the second region from a second material, different than the first material. For example, the first material can be a refractory metal, or refractory metal oxide. The second material can be SiOx. The step of selectively etching areas of the second region exposed by the non-continuous IrOx film includes exposing the substrate to an etchant that is more reactive with the second material than the IrOx.

Abstract: A method of forming a substrate for use in IC device fabrication includes preparing a silicon substrate, including doping a bulk silicon (100) substrate with ions taken from the group of ions to form a doped substrate taken from the group of doped substrates consisting of n-type doped substrates and p-type doped substrates; forming a first relaxed SiGe layer on the silicon substrate; forming a first tensile-strained silicon cap on the first relaxed SiGe layer; forming a second relaxed SiGe layer on the first tensile-strained silicon cap; forming a second tensile-strained silicon cap on the second relaxed SiGe layer; and completing an IC device.