Abstract: Embodiments provided herein describe high-k dielectric layers and methods for forming high-k dielectric layers. A substrate is provided. The substrate includes a semiconductor material. The substrate is exposed to a hafnium precursor. The substrate is exposed to a zirconium precursor. The substrate is exposed to an oxidant only after the exposing of the substrate to the hafnium precursor and the exposing of the substrate to the zirconium precursor. The exposing of the substrate to the hafnium precursor, the exposing of the substrate to the zirconium precursor, and the exposing of the substrate to the oxidant causes a layer to be formed over the substrate. The layer includes hafnium, zirconium, and oxygen.

Abstract: High-quality surface coatings, and techniques combining the atomic precision of molecular beam epitaxy and atomic layer deposition, to fabricate such high-quality surface coatings are provided. The coatings made in accordance with the techniques set forth by the invention are shown to be capable of forming silicon CCD detectors that demonstrate world record detector quantum efficiency (>50%) in the near and far ultraviolet (155 nm-300 nm). The surface engineering approaches used demonstrate the robustness of detector performance that is obtained by achieving atomic level precision at all steps in the coating fabrication process. As proof of concept, the characterization, materials, and exemplary devices produced are presented along with a comparison to other approaches.

Abstract: Defects in hydrogenated amorphous silicon are reduced by low-energy ion treatments and optional annealing. The treatments leave strongly-bonded hydrogen and other passivants in place, but increase the mobility of loosely-bonded and interstitially trapped hydrogen that would otherwise form unwanted two-level systems (TLS). The mobilized hydrogen atoms may be attracted to unused passivation sites or recombined into H2 gas and diffuse out of the deposited layer. The treatments also increase the density of the material. The optional anneal may partially crystallize the layer, further densify the layer, or both. The reduced number of defects and the increased crystallinity reduce the loss tangent of amorphous silicon dielectrics for superconducting microwave devices.

Abstract: Methods and apparatus for processing using a plasma source for the treatment of semiconductor surfaces are disclosed. The apparatus includes an outer vacuum chamber enclosing a substrate support, a plasma source (either a direct plasma or a remote plasma), and an optional showerhead. Other gas distribution and gas dispersal hardware may also be used. The plasma source may be used to generate activated species operable to alter the surface of the semiconductor materials. Further, the plasma source may be used to generate activated species operable to enhance the nucleation of deposition precursors on the semiconductor surface.

Abstract: High-quality surface coatings, and techniques combining the atomic precision of molecular beam epitaxy and atomic layer deposition, to fabricate such high-quality surface coatings are provided. The coatings made in accordance with the techniques set forth by the invention are shown to be capable of forming silicon CCD detectors that demonstrate world record detector quantum efficiency (>50%) in the near and far ultraviolet (155 nm-300 nm). The surface engineering approaches used demonstrate the robustness of detector performance that is obtained by achieving atomic level precision at all steps in the coating fabrication process. As proof of concept, the characterization, materials, and exemplary devices produced are presented along with a comparison to other approaches.

Abstract: A mobile electronic communications device includes a housing, a memory, a data entry mechanism, a display for visual data, at least one wireless transceiver configured to transmit and receive electromagnetic signals conforming to a plurality of wireless signaling protocols, and a controller. The controller is communicatively connected to the memory, data entry mechanism, and display; and is configured to send and receive data using the at least one wireless transceiver.

Abstract: A back-illuminated silicon photodetector has a layer of Al2O3 deposited on a region of a silicon oxide surface that is left uncovered, while deposition is inhibited in another region by a contact shadow mask. The Al2O3 layer is an antireflection coating. In addition, the Al2O3 layer can also provide a chemically resistant separation layer between the silicon oxide surface and additional antireflection coating layers. In one embodiment, the silicon photodetector has a delta-doped layer near (within a few nanometers of) the silicon oxide surface. The Al2O3 layer is expected to provide similar antireflection properties and chemical protection for doped layers fabricated using other methods, such as MBE, ion implantation and CVD deposition.

Abstract: In some embodiments, apparatus are provided that provide for flexible processing in high productivity combinatorial (HPC) system. The apparatus allow for interchangeable functionality that includes deposition, plasma treatment, ion beam treatment, in-situ annealing, and in-situ metrology. The apparatus are designed so that the functionality may be integrated within a single processing chamber for enhanced flexibility.

Abstract: A tunnel barrier layer in a superconducting device, such as a Josephson junction, is made from catalytically grown silicon dioxide at a low temperature (<100 C, e.g., 20-30 C) that does not facilitate oxidation or silicide formation at the superconducting electrode interface. The tunnel barrier begins as a silicon layer deposited on a superconducting electrode and covered by a thin, oxygen-permeable catalytic layer. Oxygen gas is dissociated on contact with the catalytic layer, and the resulting oxygen atoms pass through the catalytic layer to oxidize the underlying silicon. The reaction self-limits when all the silicon is converted to silicon dioxide.

Abstract: SiC substrates are cleaned and provided to a process chamber. In-situ plasma surface treatments are applied to further clean the surface of the substrate. A dielectric interface layer is deposited in-situ to passivate the surface. Metal layers having a low work function are deposited above the dielectric interface layer. The stack is annealed at about 500C in forming gas to form low resistivity ohmic contacts to the SiC substrate. SiC substrates are cleaned and provided to a process chamber. In-situ plasma surface treatments are applied to further clean the surface of the substrate. A silicon oxide dielectric interface layer is deposited in-situ to passivate the surface. Optional plasma surface treatments are applied to further improve the performance of the silicon oxide dielectric interface layer. An aluminum oxide gate dielectric layer is deposited above the silicon oxide dielectric interface layer.

Abstract: A tunnel barrier layer in a superconducting device, such as a Josephson junction, is made from catalytically grown silicon dioxide at a low temperature (<100 C, e.g., 20-30 C) that does not facilitate oxidation or silicide formation at the superconducting electrode interface. The tunnel barrier begins as a silicon layer deposited on a superconducting electrode and covered by a thin, oxygen-permeable catalytic layer. Oxygen gas is dissociated on contact with the catalytic layer, and the resulting oxygen atoms pass through the catalytic layer to oxidize the underlying silicon. The reaction self-limits when all the silicon is converted to silicon dioxide.

Abstract: SiC substrates are cleaned and provided to a process chamber. In-situ plasma surface treatments are applied to further clean the surface of the substrate. A dielectric interface layer is deposited in-situ to passivate the surface. Metal layers having a low work function are deposited above the dielectric interface layer. The stack is annealed at about 500C in forming gas to form low resistivity ohmic contacts to the SiC substrate. SiC substrates are cleaned and provided to a process chamber. In-situ plasma surface treatments are applied to further clean the surface of the substrate. A silicon oxide dielectric interface layer is deposited in-situ to passivate the surface. Optional plasma surface treatments are applied to further improve the performance of the silicon oxide dielectric interface layer. An aluminum oxide gate dielectric layer is deposited above the silicon oxide dielectric interface layer.

Abstract: Embodiments described herein provide tantalum-based copper barriers and methods for forming such barriers. A dielectric body is provided. A first layer is formed above the dielectric body. The first layer includes tantalum. A second layer is formed above the first layer. The second layer includes manganese. A third layer is formed above the second layer. The third layer includes copper.

Abstract: Metal oxide tunnel barrier layers for superconducting tunnel junctions are formed by atomic layer deposition. Both precursors include a metal (which may be the same metal or may be different). The first precursor is a metal alkoxide with oxygen bonded to the metal, and the second precursor is an oxygen-free metal precursor with an alkyl-reactive ligand such as a halogen or methyl group. The alkyl-reactive ligand reacts with the alkyl group of the alkoxide, forming a detached by-product and leaving a metal oxide monolayer. The temperature is selected to promote the reaction without causing the metal alkoxide to self-decompose. The oxygen in the alkoxide precursor is bonded to a metal before entering the chamber and remains bonded throughout the reaction that forms the monolayer. Therefore, the oxygen used in this process has no opportunity to oxidize the underlying superconducting electrode.

Abstract: In some embodiments, apparatus are provided that provide for flexible processing in high productivity combinatorial (HPC) system. The apparatus allow for interchangeable functionality that includes deposition, plasma treatment, ion beam treatment, in-situ annealing, and in-situ metrology. The apparatus are designed so that the functionality may be integrated within a single processing chamber for enhanced flexibility.

Abstract: In a “window-junction” formation process for Josephson junction fabrication, a spacer dielectric is formed over the first superconducting electrode layer, then an opening (the “window” is formed to expose the part of the electrode layer to be used for the junction. In an atomic layer deposition (ALD) chamber (or multi-chamber sealed system) equipped with direct or remote plasma capability, the exposed part of the electrode is sputter-etched with Ar, H2, or a combination to remove native oxides, etch residues, and other contaminants. Optionally, an O2 or O3 pre-clean may precede the sputter etch. When the electrode is clean, the tunnel barrier layer is deposited by ALD in-situ without further oxidant exposure.

Abstract: Systems and methods for rapid generation of ALD saturation curves using segmented spatial ALD are disclosed. Methods include introducing a substrate, having a plurality of substrate segment regions, into a processing chamber. The substrate may be disposed upon a pedestal within the chamber. Sequentially exposing the plurality of segment regions to a precursor within the chamber at a first processing temperature. Afterwards, purging the precursor from the chamber and then sequentially exposing each plurality of segment regions to a reactant within the chamber at the first processing temperature. Afterwards, purging the reactant from the chamber. Repeat sequentially exposing the plurality of segment regions to the precursor and the reactant for a plurality of cycles. Each segment region may be sequentially exposed to the precursor for a unique processing time. The pedestal may be rotated prior to exposing each next segment region to the precursor and the reactant.

Abstract: Defects in hydrogenated amorphous silicon are reduced by low-energy ion treatments and optional annealing. The treatments leave strongly-bonded hydrogen and other passivants in place, but increase the mobility of loosely-bonded and interstitially trapped hydrogen that would otherwise form unwanted two-level systems (TLS). The mobilized hydrogen atoms may be attracted to unused passivation sites or recombined into H2 gas and diffuse out of the deposited layer. The treatments also increase the density of the material. The optional anneal may partially crystallize the layer, further densify the layer, or both. The reduced number of defects and the increased crystallinity reduce the loss tangent of amorphous silicon dielectrics for superconducting microwave devices.

Abstract: A interconnect structure for superconducting devices uses a material with a high melting point for the superconductive wiring; examples include refractory metals such as niobium. Because the wiring is tolerant of high temperatures, the interlayer dielectric (e.g., amorphous silicon with or without small amounts of passivants such as hydrogen or fluorine) may be subjected to rapid thermal annealing to reduce defects by driving off excess hydrogen, and optionally partially crystallizing the material.

Abstract: Methods and apparatus for processing using a remote plasma source are disclosed. The apparatus includes an outer chamber enclosing a substrate support, a remote plasma source, and a showerhead. A substrate heater can be mounted in the substrate support. A transport system moves the substrate support and is capable of positioning the substrate. The plasma system may be used to generate activated species. The activated species can be used to treat the surfaces of low-k and/or ultra low-k dielectric materials to facilitate improved deposition of diffusion barrier materials.