Abstract: A dual gate strained-Si MOSFET with thin SiGe dislocation regions and a method for fabricating the same are provided. The method forms a first layer of relaxed SiGe overlying a substrate, having a thickness of less than 5000 ?; forms a second layer of relaxed SiGe overlying the substrate and adjacent to the first layer of SiGe, having a thickness of less than 5000 ?; forms a layer of strained-Si overlying the first and second SiGe layers; forms a shallow trench isolation region interposed between the first SiGe layer and the second SiGe layer; forms an p-well in the substrate and the overlying first layer of SiGe; forming forms a p-well in the substrate and the overlying second layer of SiGe; forms channel regions, in the strained-Si, and forms PMOS and NMOS transistor source and drain regions.

Abstract: A method of fabricating a multi-level 3D memory array includes: preparing a wafer and peripheral circuits thereon; layers of metal, memory resistor material, and metal are deposited, patterned and etched. The steps of the method of the invention are repeated for N levels of a memory array.

Abstract: A germanium (Ge) short wavelength infrared (SWIR) imager and associated fabrication process are provided. The imager comprises a silicon (Si) substrate with doped wells. An array of pin diodes is formed in a relaxed Ge-containing film overlying the Si substrate, each pin diode having a flip-chip interface. There is a Ge/Si interface, and a doped Ge-containing buffer interposed between the Ge-containing film and the Ge/Si interface. An array of Si CMOS readout circuits is bonded to the flip-chip interfaces. Each readout circuit has a zero volt diode bias interface.

Abstract: A method of fabricating local interconnect on a silicon-germanium 3D CMOS includes fabricating an active silicon CMOS device on a silicon substrate. An insulator layer is deposited on the silicon substrate and a seed window is opened through the insulator layer to the silicon substrate and to a silicon CMOS device gate. A germanium thin film is deposited on the insulator layer and into windows, forming a contact between the germanium thin film and the silicon device. The germanium thin film is encapsulated in a dielectric material. The wafer is heated at a temperature sufficient to flow the germanium, while maintaining the other layers in a solid condition. The wafer is cooled to solidify the germanium as single crystal germanium and as polycrystalline germanium, which provides local interconnects. Germanium CMOS devices may be fabricated on the single crystal germanium thin film.

Abstract: The present invention discloses a novel transistor structure employing semiconductive metal oxide as the transistor conductive channel. By replacing the silicon conductive channel with a semiconductive metal oxide channel, the transistors can achieve simpler fabrication process and could realize 3D structure to increase circuit density. The disclosed semiconductive metal oxide transistor can have great potential in ferroelectric non volatile memory device with the further advantages of good interfacial properties with the ferroelectric materials, possible lattice matching with the ferroelectric layer, reducing or eliminating the oxygen diffusion problem to improve the reliability of the ferroelectric memory transistor. The semiconductive metal oxide film is preferably a metal oxide exhibiting semiconducting properties at the transistor operating conditions, for example, In2O3 or RuO2.

Abstract: An MFIS memory array having a plurality of MFIS memory transistors with a word line connecting a plurality of MFIS memory transistor gates, wherein all MFIS memory transistors connected to a common word line have a common source, each transistor drain serves as a bit output, and all MFIS channels along a word line are separated by a P+ region and are further joined to a P+ substrate region on an SOI substrate by a P+ region is provided. Also provided are methods of making an MFIS memory array on an SOI substrate; methods of performing a block erase of one or more word lines, and methods of selectively programming a bit.

Abstract: A method of selectively etching a three-layer structure consisting of SiO2, In2O3, and titanium, includes etching the SiO2, stopping at the titanium layer, using C3F8 in a range of between about 10 sccm to 30 sccm; argon in a range of between about 20 sccm to 40 sccm, using an RF source in a range of between about 1000 watts to 3000 watts and an RF bias in a range of between about 400 watts to 800 watts at a pressure in a range of between about 2 mtorr to 6 mtorr; and etching the titanium, stopping at the In2O3 layer, using BCl in a range of between about 10 sccm to 50 sccm; chlorine in a range of between about 40 sccm to 80 sccm, a Tcp in a range of between about 200 watts to 500 watts at an RF bias in a range of between about 100 watts to 200 watts at a pressure in a range of between about 4 mtorr to 8 mtorr.

Abstract: An electroluminescence (EL) device and a method are provided for fabricating said device with a nanotip electrode. The method comprises: forming a bottom electrode with nanotips; forming a Si phosphor layer adjacent the nanotips; and, forming a transparent top electrode. The Si phosphor layer is interposed between the bottom and top electrodes. The nanotips may have a tip base size of about 50 nanometers, or less, a tip height in the range of 5 to 50 nm, and a nanotip density of greater than 100 nanotips per square micrometer. Typically, the nanotips are formed from iridium oxide (IrOx) nanotips. A MOCVD process forms the Ir bottom electrode. The IrOx nanotips are grown from the Ir. In one aspect, the Si phosphor layer is a SRSO layer. In response to an SRSO annealing step, nanocrystalline SRSO is formed with nanocrystals having a size in the range of 1 to 10 nm.

Abstract: A method of controlling strain in a single-crystal, epitaxial oxide film, includes preparing a silicon substrate; forming a silicon alloy layer taken from the group of silicon alloy layer consisting of Si1-xGex and Si1-yCy on the silicon substrate; adjusting the lattice constant of the silicon alloy layer by selecting the alloy material content to adjust and to select a type of strain for the silicon alloy layer; depositing a single-crystal, epitaxial oxide film, by atomic layer deposition, taken from the group of oxide films consisting of perovskite manganite materials, single crystal rare-earth oxides and perovskite oxides, not containing manganese; and rare earth binary and ternary oxides, on the silicon alloy layer; and completing a desired device.

Abstract: A method is provided for forming a NanoElectroChemical (NEC) cell. The method provides a bottom electrode with a top surface. Nanowire shells are formed. Each nanowire shell has a nanowire and a sleeve, with the nanowire connected to the bottom electrode top surface. A top electrode is formed overlying the nanowire shells. A main cavity is formed between the top electrode and bottom electrodes, partially displaced by a first plurality of nanowire shells. Electrolyte cavities are formed between the sleeves and nanowires by etching the first sacrificial layer. In one aspect, electrolyte cavities are formed between the bottom electrode top surface and a shell coating layer joining the sleeve bottom openings. Then, the main and electrolyte cavities are filled with either a liquid or gas phase electrolyte. In a different aspect, the first sacrificial layer is a solid phase electrolyte that is not etched away.

Abstract: A method of fabricating a photovoltaic cell for use in a solar cell structure includes preparing a first substrate; preparing a TiO2 precursor; preparing a cold wall CVD chamber; placing the first substrate in the cold wall CVD chamber; forming a transparent conducting electrode on the first substrate; depositing a porous column TiO2 film on the transparent conducting electrode; depositing a photosensitive material in and on the porous column TiO2 film; forming a top electrode on the photovoltaic cell; and incorporating the photovoltaic cell into a solar cell structure. The method of the invention is suitable for forming photovoltaic cells which may be of the dye-sensitized solar cell (DSSC) type, having a liquid or solid-state electrolyte therein, or an ordered organic-inorganic heterojunction photovoltaic cell.

Abstract: A method is provided for transferring a single-crystal silicon (Si) film to a glass substrate. The method deposits a germanium (Ge)-containing material overlying a Si wafer, forming a sacrificial Ge-containing film. A single-crystal Si film is formed overlying the sacrificial Ge-containing film. The Si film surface is bonded to a transparent substrate, forming a bonded substrate. The bonded substrate is immersed in a Ge etching solution to remove the sacrificial Ge-containing film, which separates the transparent substrate from the Si wafer. The result is a transparent substrate with an overlying single crystal Si film. Optionally, channels can be formed to distribute the Ge etching solution, and promote the removal of the Ge-containing film.

Abstract: A method of fabricating a germanium photo detector includes preparing a silicon substrate wafer and depositing and planarizing a silicon oxide layer on the silicon substrate. Contact holes are formed in the silicon oxide layer. An N+ epitaxial germanium layer is grown on the silicon oxide layer and in the contact holes. An N+ germanium layer is formed by ELO. The structure is smoothed and thinned. An intrinsic germanium layer is grown on the N+ epitaxial germanium layer. A P+ germanium layer is formed on the intrinsic germanium layer and a silicon oxide overcoat is deposited. A window is opened through the silicon oxide overcoat to the P+ germanium layer. A layer of conductive material is deposited on the silicon oxide overcoat and in the windows therein. The conductive material is etched to form individual sensing elements.

Abstract: A method of fabricating a germanium infrared sensor for a CMOS imager includes preparation of a donor wafer, including: ion implantation into a silicon wafer to form a P+ silicon layer; growing an epitaxial germanium layer on the P+silicon layer, forming a silicon-germanium interface; cyclic annealing; and implanting hydrogen ions to a depth at least as deep as the P+ silicon layer to form a defect layer; preparing a handling wafer, including: fabricating a CMOS integrated circuit on a silicon substrate; depositing a layer of refractory metal; treating the surfaces of the donor wafer and the handling wafer for bonding; bonding the handling wafer and the donor wafer to form a bonded structure; splitting the bonded structure along the defect layer; depositing a layer of indium tin oxide on the germanium layer; completing the IR sensor.

Abstract: A method of fabricating a germanium photo detector includes preparing a silicon substrate; depositing and planarizing a silicon oxide layer; forming contact holes in the silicon oxide layer which communicate with the underlying silicon substrate; growing an epitaxial germanium layer of a first type on the silicon oxide layer and in the contact holes; growing an intrinsic germanium layer on the epitaxial germanium layer and any exposed silicon oxide layer; growing a germanium layer of a second type on the intrinsic germanium layer and any exposed silicon oxide layer; depositing a layer of covering material take from the group of materials consisting of polysilicon, polysilicon-germanium and In2O3—SnO2; and etching the covering material to form individual sensing elements.

Abstract: A compound semiconductor-on-silicon (Si) wafer with a Si nanowire buffer layer is provided, along with a corresponding fabrication method. The method forms a Si substrate. An insulator layer is formed overlying the Si substrate, with Si nanowires having exposed tips. Compound semiconductor is selectively deposited on the Si nanowire tips. A lateral epitaxial overgrowth (LEO) process grows compound semiconductor from the compound semiconductor-coated Si nanowire tips, to form a compound semiconductor layer overlying the insulator. Typically, the insulator layer overlying the Si substrate is a thermally soft insulator (TSI), silicon dioxide, or SiXNY, where X?3 and Y?4. The compound semiconductor can be GaN, GaAs, GaAlN, or SiC. In one aspect, the Si nanowire tips are carbonized, and SiC is selectively deposited overlying the carbonized Si nanowire tips, prior to the selective deposition of compound semiconductor on the Si nanowire tips.

Abstract: A floating body germanium (Ge) phototransistor with a photo absorption threshold bias region, and an associated fabrication process are presented. The method includes: providing a p-doped Silicon (Si) substrate; selectively forming an insulator layer overlying a first surface of the Si substrate; forming an epitaxial Ge layer overlying the insulator layer; forming a channel region in the Ge layer; forming a gate dielectric, gate electrode, and gate spacers; forming source/drain (S/D) regions in the Ge layer; and, forming a photo absorption threshold bias region in the Ge layer, adjacent the channel region. In one aspect, the second S/D region has a length, longer than the first S/D length. The photo absorption threshold bias region underlies the second S/D region. Alternately, the second S/D region is separated from the channel by an offset, and the photo absorption threshold bias region is the offset in the Ge layer, after a light p-doping.

Abstract: A silicon/germanium (SiGe) superlattice thermal sensor is provided with a corresponding fabrication method. The method forms an active CMOS device in a first Si substrate, and a SiGe superlattice structure on a second Si-on-insulator (SOI) substrate. The first substrate is bonded to the second substrate, forming a bonded substrate. An electrical connection is formed between the SiGe superlattice structure and the CMOS device, and a cavity is formed between the SiGe superlattice structure and the bonded substrate.

Abstract: A memory array layer for use in a 3D RRAM is formed, with peripheral circuitry, on a silicon substrate; layers of silicon oxide, bottom electrode material, silicon oxide, resistor material, silicon oxide, silicon nitride, silicon oxide, top electrode and covering oxide are deposited and formed. Multiple memory array layers may be formed on top of one another. The RRAM of the invention may be programmed in a single step or a two step programming process.

Abstract: A dry etch process is described for selectively etching silicon nitride from conductive oxide material for use in a semiconductor fabrication process. Adding an oxidant in the etch gas mixture could increase the etch rate for the silicon nitride while reducing the etch rate for the conductive oxide, resulting in improving etch selectivity. The disclosed selective etch process is well suited for ferroelectric memory device fabrication using conductive oxide/ferroelectric interface having silicon nitride as the encapsulated material for the ferroelectric.