In one embodiment, a method to form a superconductor device includes depositing a crystalline layer having a preferred crystallographic orientation on a substrate and forming an oriented superconductor layer comprising an oriented superconductor material on the crystalline layer. A metallic layer is formed on the superconductor layer and a mask is provided proximate the substrate to define a protected portion of the oriented superconductor layer and an exposed portion of the oriented superconductor layer. The exposed portion of the oriented superconductor layer is removed without etching the protected portion of the oriented superconductor layer.

The present invention relates to an optoelectronic device comprising: (a) a substrate comprising at least one first electrode, which at least one first electrode comprises a first electrode material, and at least one second electrode, which at least one second electrode comprises a second electrode material; and (b) a photoactive material disposed on the substrate, which photoactive material is in contact with the at least one first electrode and the at least one second electrode, wherein the substrate comprises: a layer of the first electrode material; and, disposed on the layer of the first electrode material, a layer of an insulating material, which layer of an insulating material partially covers the layer of the first electrode material; and, disposed on the layer of the insulating material, the second electrode material, and wherein the photoactive material comprises a crystalline compound, which crystalline compound comprises: one or more first cations selected from metal or metalloid cations; one or more second cations selected from Cs.sup.+RB.sup.+, K.sup.+, NH.sup.4 + and organic cations; and one or more halide or chalcogenide anions. A substrate comprising a first and second electrode and processes are also described.

The invention relates to a method for producing a composite comprising a high-temperature superconductor (HTS) layer based on rare earth metal-barium-copper oxide on a substrate with defined biaxial texture, having the following steps: applying a first HTS coating solution to the substrate, drying the first HTS coating solution to produce a first film, pyrolyzing the first film to produce a first pyrolyzed sublayer, removing an interfacial layer on the upper side of the first pyrolyzed sublayer to produce a first pyrolyzed sublayer with reduced layer thickness, applying a second HTS coating solution to the first pyrolyzed sublayer with reduced layer thickness, drying the second HTS coating solution to produce a second film, pyrolyzing the second film to produce a second pyrolyzed sublayer, optionally forming one or more further pyrolyzed sublayers on the second pyrolyzed sublayer, and crystallizing the overall layer formed from the pyrolyzed sublayers to complete the HTS layer, wherein the removal of the interfacial layer in step D) is effected in such a way that a texture determined by the defined biaxial texture of the substrate is transferred to the first and also to the second pyrolyzed sublayer, and also to a product producible by such a method.

A configuration and a method of constructing a high-temperature superconductor tape including a plurality superconducting filaments sandwiched between a substrate and an overlayer comprising compliant material extending to the substrate through gaps between each superconducting filament thereby isolating each superconducting filament.

A method for fabricating an electrochemical sensing test piece comprises steps: forming an electrode layer on a substrate; etching the electrode layer to reduce the area of the electrode layer to be smaller than the area of the substrate, wherein the electrode layer has a test zone and a reading zone neighboring the test zone; forming an insulation member surrounding the test zone and covering the perimeter of the test zone; forming an enzyme layer on the test zone; and forming an insulation layer on the enzyme layer and the periphery of the reading zone and fabricating the insulation layer to have an opening revealing a portion of the enzyme layer. The insulation member fixes the effective reaction area of the tested material and increases measurement accuracy.

A wavelength tunable gain medium with the use of micro-electromechanical system (MEMS) based Fabry-Perot (FP) filter cavity tuning is provided as a tunable laser. The system comprises a laser cavity and a filter cavity for wavelength selection. The laser cavity consists of a gain medium such as a Semiconductor Optical Amplifier (SOA), two collimating lenses and an end reflector. The MEMS-FP filter cavity comprises a fixed reflector and a moveable reflector, controllable by electrostatic force. By moving the MEMS reflector, the wavelength can be tuned by changing the FP filter cavity length. The MEMS FP filter cavity displacement can be tuned discretely with a step voltage, or continuously by using a continuous driving voltage. The driving frequency for continuous tuning can be a resonance frequency or any other frequency of the MEMS structure, and the tuning range can cover different tuning ranges such as 30 nm, 40 nm, and more than 100 nm.

A method for fabricating an electrochemical sensing test piece comprises steps: forming an electrode layer on a substrate; etching the electrode layer to reduce the area of the electrode layer to be smaller than the area of the substrate, wherein the electrode layer has a test zone and a reading zone neighboring the test zone; forming an insulation member surrounding the test zone and covering the perimeter of the test zone; forming an enzyme layer on the test zone; and forming an insulation layer on the enzyme layer and the periphery of the reading zone and fabricating the insulation layer to have an opening revealing a portion of the enzyme layer. The insulation member fixes the effective reaction area of the tested material and increases measurement accuracy.

A wavelength tunable gain medium with the use of micro-electromechanical system (MEMS) based Fabry-Perot (FP) filter cavity tuning is provided as a tunable laser. The system comprises a laser cavity and a filter cavity for wavelength selection. The laser cavity consists of a gain medium such as a Semiconductor Optical Amplifier (SOA), two collimating lenses and an end reflector. The MEMS-FP filter cavity comprises a fixed reflector and a moveable reflector, controllable by electrostatic force. By moving the MEMS reflector, the wavelength can be tuned by changing the FP filter cavity length. The MEMS FP filter cavity displacement can be tuned discretely with a step voltage, or continuously by using a continuous driving voltage. The driving frequency for continuous tuning can be a resonance frequency or any other frequency of the MEMS structure, and the tuning range can cover different tuning ranges such as 30 nm, 40 nm, and more than 100 nm.

Silicided nanowires as nanobridges in Josephson junctions. A superconducting silicided nanowire is used as a weak-link bridge in a Josephson junction, and a fabrication process is employed to produce silicided nanowires that includes patterning two junction banks and a rough nanowire from a silicon substrate, reshaping the nanowire through hydrogen annealing, and siliciding the nanowire by introduction of a metal into the nanowire structure.

A method for forming a plurality of filaments, such that each filament is superconducting. The method includes providing a substrate having first and second sides. The substrate has a plurality of grooves in the first side of the substrate having a coating of a superconducting material so that for each groove within the plurality of grooves. A first part of the coating on a first side of a feature of the groove is separated from a second part of the coating on a second side of the feature of the groove. The second side of the feature of the groove is opposite of the first side of the groove, with removing from the second side of the substrate, at least a part of the substrate, to remove at least a connection from the first part of the coating to the second part of the coating via the substrate.