Abstract: Provided are an electroluminescence (EL) device and corresponding method for forming a rare earth element-doped silicon (Si)/Si dioxide (SiO2) lattice structure. The method comprises: providing a substrate; DC sputtering a layer of amorphous Si overlying the substrate; DC sputtering a rare earth element; in response, doping the Si layer with the rare earth element; DC sputtering a layer of SiO2 overlying the rare earth-doped Si; forming a lattice structure; annealing; and, in response to the annealing, forming nanocrystals in the rare-earth doped Si having a grain size in the range of 1 to 5 nanometers (nm). In one aspect, the rare earth element and Si are co-DC sputtered. Typically, the steps of DC sputtering Si, DC sputtering the rare earth element, and DC sputtering the SiO2 are repeated 5 to 60 cycles, so that the lattice structure includes the plurality (5-60) of alternating SiO2 and rare earth element-doped Si layers.

Abstract: A ZnO film with a C-axis preference is provided with a corresponding fabrication method. The method includes: forming a substrate; forming an amorphous Al2O3 film overlying the substrate; and, forming a ZnO film overlying the Al2O3 film at a substrate temperature of about 170° C., having a C-axis preference responsive to the adjacent Al2O3 film. The substrate can be a material such as Silicon (Si) (100), Si (111), Si (110), quartz, glass, plastic, or zirconia. The Al2O3 film can be deposited using a chemical vapor deposition (CVD), atomic layer deposition (ALD), or sputtering process. Typically, the Al2O3 layer has a thickness in the range of about 3 to 15 nanometers (nm). The step of forming the ZnO film having a C-axis preference typically means that the ZnO film has a (002) peak at least 5 times greater than the (100) peak, as measured by X-ray diffraction (XRD).

Abstract: A method of forming a microlens array includes preparing a substrate; fabricating a photosensitive array on the substrate; depositing a layer of lens material on the photosensitive array; depositing and patterning photoresist on the lens material, wherein patterning includes forming a photoresist region having a solid curved upper surface and a substantially rectangular base on the lens material layer; developing the photoresist; reflowing the photoresist; and processing the lens material for form a microlens array.

Abstract: A ZnO asperity-covered carbon nanotube (CNT) device has been provided, along with a corresponding fabrication method. The method comprises: forming a substrate; growing CNTs from the substrate; conformally coating the CNTs with ZnO; annealing the ZnO-coated CNTs; and, forming ZnO asperities on the surface of the CNTs in response to the annealing. In one aspect, the ZnO asperities have a density in the range of about 100 to 1000 ZnO asperities per CNT. The density is dependent upon the deposited ZnO film thickness and annealing parameters. The CNTs are conformally coating with ZnO using a sputtering, chemical vapor deposition (CVD), spin-on, or atomic layer deposition (ALD). For example, an ALD process can be to deposit a layer of ZnO over the CNTs having a thickness in the range of 1.2 to 200 nanometers (nm).

Abstract: A method is provided for forming an electroluminescent device. The method comprises: providing a type IV semiconductor material substrate; forming a p+/n+ junction in the substrate, typically a plurality of interleaved p+/n+ junctions are formed; and, forming an electroluminescent layer overlying the p+/n+ junction(s) in the substrate. The type IV semiconductor material substrate can be Si, C, Ge, SiGe, or SiC. For example, the substrate can be Si on insulator (SOI), bulk Si, Si on glass, or Si on plastic. The electroluminescent layer can be a material such as nanocrystalline Si, nanocrystalline Ge, fluorescent polymers, or type II–VI materials such as ZnO, ZnS, ZnSe, CdSe, and CdS. In some aspect, the method further comprises forming an insulator film interposed between the substrate and the electroluminescent layer. In another aspect, the method comprises forming a conductive electrode overlying the electroluminescent layer.

Abstract: An oxide interface and a method for fabricating an oxide interface are provided. The method comprises forming a silicon layer and an oxide layer overlying the silicon layer. The oxide layer is formed at a temperature of less than 400° C. using an inductively coupled plasma source. In some aspects of the method, the oxide layer is more than 20 nanometers (nm) thick and has a refractive index between 1.45 and 1.47. In some aspects of the method, the oxide layer is formed by plasma oxidizing the silicon layer, producing plasma oxide at a rate of up to approximately 4.4 nm per minute (after one minute). In some aspects of the method, a high-density plasma enhanced chemical vapor deposition (HD-PECVD) process is used to form the oxide layer. In some aspects of the method, the silicon and oxide layers are incorporated into a thin film transistor.

Abstract: A method of microlens fabrication for use in a photosensor includes preparing a photodetector element array which is sensitive to light in a specific color domain and depositing microlens material on the photodetector element array. The structure is coated with photoresist, and the photoresist is masked and exposed in a separate exposure for each color in the color domain. The photoresist is developed and the microlens material etched to form a microlens array.

Abstract: A method of SrCu2O2 spin-on precursor synthesis and low temperature p-type thin film deposition, includes preparing a wafer to receive a spin-coating thereon; selecting metalorganic compounds to form a SrCu2O2 precursor, mixing and refluxing the metalorganic compounds to form a precursor mixture; filtering the precursor mixture to produce a spin-coating precursor; applying the spin-coating precursor to the wafer in a two-step spin coating procedure; baking the spin-coated wafer using a hot-plate bake to evaporate substantially all of the solvents; and annealing the spin-coated wafer to form a SrCu2O2 layer thereon in a two-step post-anneal process.

Abstract: A method for selective ALD of ZnO on a wafer preparing a silicon wafer; patterning the silicon wafer with a blocking agent in selected regions where deposition of ZnO is to be inhibited, wherein the blocking agent is taken from a group of blocking agents includes isopropyl alcohol, acetone and deionized water; depositing a layer of ZnO on the wafer by ALD using diethyl zinc and H2O at a temperature of between about 140° C. to 170° C.; and removing the blocking agent from the wafer.

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 of fabricating a nanowire sensor device structure includes preparing a substrate, having a silicon base layer, a buried oxide layer in the silicon base layer, a top silicon layer on the buried oxide layer, and a doped well in the silicon base layer; forming a silicon island from the top silicon layer; etching the buried oxide layer to undercut the silicon island in some instances; depositing a seed layer of polycrystalline ZnO over the silicon island, the buried oxide layer, the doped well and the silicon base layer; selectively removing the polycrystalline ZnO from the silicon island; growing and structuring ZnO nanostructures on the seed layer of ZnO; treating the ZnO nanostructures to sensitize the ZnO nanostructures to a desired application; depositing a layer of insulating material; patterning and etching the insulating material; and metallizing the nanowire device structure.

Abstract: A method is provided for forming a ZnO Si N—I—N EL device. The method comprises: forming an n-doped Si layer; forming a Si oxide (SiO2) layer overlying the n-doped Si layer; forming an n-type ZnO layer overlying the SiO2 layer; and, forming an electrode overlying the ZnO layer. The electrode can be a transparent material such as indium tin oxide, zinc oxyfluoride, or a conductive plastic. The n-doped Si layer can be polycrystalline or single-crystal Si. In some aspects, the Si oxide layer has a thickness in the range of 1 to 20 nm. More preferably, the thickness is 2 to 5 nm. The ZnO layer thickness is in the range of 10 to 200 nm.

Abstract: MOSFET gate structures are provided comprising a niobium monoxide gate, overlying a gate dielectric. The niobium monoxide gate may have a low work function suitable for use as an NMOS gate.

Abstract: MOSFET gate structures are provided comprising a niobium monoxide gate, overlying a gate dielectric. The niobium monoxide gate may have a low work function suitable for use as an NMOS gate.

Abstract: A method for selective ALD of ZnO on a wafer preparing a silicon wafer; patterning the silicon wafer with a blocking agent in selected regions where deposition of ZnO is to be inhibited, wherein the blocking agent is taken from a group of blocking agents includes isopropyl alcohol, acetone and deionized water; depositing a layer of ZnO on the wafer by ALD using diethyl zinc and H2O at a temperature of between about 140° C. to 170° C.; and removing the blocking agent from the wafer.

Abstract: A method of fabricating a nanowire CHEMFET sensor mechanism includes preparing a silicon substrate; depositing a polycrystalline ZnO seed layer on the silicon substrate; patterning and etching the polycrystalline ZnO seed layer; depositing an insulating layer over the polycrystalline ZnO seed layer and the silicon substrate; patterning and etching the insulating layer to form contact holes to a source region and a drain region; metallizing the contact holes to form contacts for the source region and the drain region; depositing a passivation dielectric layer over the insulating layer and the contacts; patterning the passivation layer and etching to expose the polycrystalline ZnO seed layer between the source region and the drain region; and growing ZnO nanostructures on the exposed ZnO seed layer to form a ZnO nanostructure CHEMFET sensor device.

Abstract: A method is provided for forming a silicon oxide (SiOx) thin-film with embedded nanocrystalline silicon (Si). The method deposits SiOx, where x is in the range of 1 to 2, overlying a substrate, using a high-density (HD) plasma-enhanced chemical vapor deposition (PECVD) process. As a result, the SiOx thin-film is embedded with nanocrystalline Si. The HD PECVD process may use an inductively coupled plasma (ICP) source, a substrate temperature of less than about 400° C., and an oxygen source gas with a silicon precursor. In one aspect, a hydrogen source gas and an inert gas are used, where the ratio of oxygen source gas to inert gas is in the range of about 0.02 to 5. The SiOx thin-film with embedded nanocrystalline Si typically has a refractive index in the range of about 1.6 to 2.2, with an extinction coefficient in the range of 0 to 0.5.

Abstract: A device and a fabrication method are provided for a ZnO nanotip electroluminescence (EL) device on a silicon (Si) substrate. The method includes: forming a Si substrate; forming a bottom contact overlying the Si substrate; forming a seed layer overlying the bottom contact; forming ZnO nanotips with tops, overlying the seed layer; forming an insulating film overlying the ZnO nanotips; etching the insulating film; exposing the ZnO nanotip tops; and, forming a transparent top electrode overlying the exposed ZnO nanotip tops. In one aspect, after forming the ZnO nanotips, an ALD process can be used to coat the ZnO nanotips with a material such as Al2O3 or HfO2. The seed layer can be ZnO or ZnO:Al, formed using a deposition process such as sputtering, chemical vapor deposition (CVD), spin-on, or atomic layer deposition (ALD).

Abstract: A device and a fabrication method are provided for an EL device with a nanotip-contoured phosphor layer. The method comprises: forming a bottom electrode with nanotips; forming a phosphor layer overlying the bottom electrode, having irregularly-shaped top and bottom surfaces; and, forming a top electrode overlying the phosphor layer. The bottom electrode top surface has a nanotip contour, and the phosphor layer irregularly-shaped top and bottom surfaces have contours approximately matching the bottom electrode top surface nanotip contour. In one aspect, a contoured bottom dielectric is interposed between the bottom electrode and the phosphor layer, having top and bottoms surfaces with contours approximately matching the nanotip contour. Likewise, a top dielectric may be interposed between the top electrode and the phosphor layer, having a bottom surface with a contour approximately matching the contour of phosphor layer top surface.

Abstract: A method of making CMOS devices on strained silicon on glass includes preparing a glass substrate, including forming a strained silicon layer on the glass substrate; forming a silicon oxide layer by plasma oxidation of the strained silicon layer; depositing a layer of doped polysilicon on the silicon oxide layer; forming a polysilicon gate; implanting ions to form a LDD structure; depositing and forming a spacer dielectric on the gate structure; implanting and activation ions to form source and drain structures; depositing a layer of metal film; annealing the layer of metal film to form salicide on the source, drain and gate structures; removing any unreacted metal film; depositing a layer of interlayer dielectric; and forming contact holes and metallizing.