Disclosed in the present invention is an enzyme-free glucose detection chip, including: a substrate; a detection portion, disposed on an end surface of the substrate; a plurality of protrusions, disposed at the detection portion; a conductive layer, disposed on a surface of the substrate having the protrusions; and a plurality of gold nanoparticles, dispersed on surfaces of the protrusions. In the enzyme-free glucose detection chip disclosed in the present invention, protrusions having gold nanoparticles are used as electrodes, are structures on a micrometer scale and a nanometer scale, and can directly react with glucose without any glucose oxidase or/and any medium.

Various embodiments provide for systems and techniques for the successful fabrication of metal oxide (TMO)-on-glass layer stacks via direct deposition. The resulting samples feature epitaxial, strontium titanate (STO) or barium titanate (BTO) films on silicon dioxide (SiO.sub.2) layers, forming STO- or BTO-buffered SiO.sub.2 pseudo-substrates. As the integration of TMO films on silicon rely on an STO or BTO buffer layer, a wide variety of TMO-based integrated devices (e.g., circuits, waveguides, etc.) can be fabricated from the TMO-on-glass platform of the present technology. Moreover, the STO, or the BTO, survives the fabrication process without a corresponding degradation of crystalline quality, as evidenced by various objective measures.

Various embodiments provide for systems and techniques for the successful fabrication of metal oxide (TMO)-on-glass layer stacks via direct deposition. The resulting samples feature epitaxial, strontium titanate (STO) or barium titanate (BTO) films on silicon dioxide (SiO.sub.2) layers, forming STO- or BTO-buffered SiO.sub.2 pseudo-substrates. As the integration of TMO films on silicon rely on an STO or BTO buffer layer, a wide variety of TMO-based integrated devices (e.g., circuits, waveguides, etc.) can be fabricated from the TMO-on-glass platform of the present technology. Moreover, the STO, or the BTO, survives the fabrication process without a corresponding degradation of crystalline quality, as evidenced by various objective measures.

A method of forming a high-conductivity electrical interconnect on a substrate may include forming a graphene film with a plurality of graphene members, depositing a metal over the graphene film, and providing a metallic overlay that connects the plurality of graphene members together through the depositing operation to form a covered graphene film.

A target for sputtering which enables to attain high rate film-formation of a transparent conductive film suitable for a blue LED or a solar cell. A oxide sintered body includes an indium oxide and a cerium oxide, and one or more oxide of titanium, zirconium, hafnium, molybdenum and tungsten. The cerium content is 0.3 to 9% by atom, as an atomicity ratio of Ce/(In+Ce), and the content of cerium is equal to or lower than 9% by atom, as an atomicity ratio of Ce/(In+Ce). The oxide sintered body has an In.sub.2O.sub.3 phase of a bixbyite structure has a CeO.sub.2 phase of a fluorite-type structure finely dispersed as crystal grains having an average particle diameter of equal to or smaller than 3 μm.

An etching chamber is equipped with an actively-cooled element preferentially adsorbs volatile compounds that are evolved from a polymeric layer of a wafer during etching, which compounds will act as contaminants if re-deposited on the wafer, for example on exposed metal contact portions where they may interfere with subsequent deposition of metal contact layers. In desirable embodiments, a getter sublimation pump is also provided in the etching chamber as a source of getter material. Methods of etching in such a chamber are also disclosed.

This invention relates to the in-vacuum rotational device on a cylindrical magnetron sputtering source where the target or target elements of the target construction of such device are enabled to rotate without the need of a vacuum to atmosphere or vacuum to coolant dynamic seal. This invention relates to the use of the device in vacuum plasma technology where a plasma discharge, or any other appropriate source of energy such as arcs, laser, which can be applied to the target or in its vicinity would produce suitable coating deposition or plasma treatment on components of different nature. This invention also relates but not exclusively to the use of the device in sputtering, magnetron sputtering, arc, plasma polymerization, laser ablation and plasma etching. This invention also relates to the use of such devices and control during non-reactive and reactive processes, with or without feedback plasma process control. This invention also relates to the arrangement of these devices as a singularity or a plurality of units. This invention also relates to the target construction which can be used in such device. This invention also relates to the use of these devices in different power modes such as DC, DC pulsed, RF, AC, AC dual, HIPIMS, or any other powering mode in order to generate a plasma, such as sputtering plasma, plasma arc, electron beam evaporation, plasma polymerization plasma, plasma treatment or any other plasma generated for the purpose of a process, for example, and not exclusively, as deposition process or surface treatment process, etc.

A method for producing a solid lithium-based electrolyte for a solid microbattery implements the cathode sputtering of a lithium-based target material on an object supported by a substrate holder. A grid made of lithium-free electrically conductive material is interposed between the object and the lithium-based target material, the grid being electrically connected to the substrate holder.

A method for producing a solid lithium-based electrolyte for a solid microbattery implements the cathode sputtering of a lithium-based target material on an object supported by a substrate holder. A grid made of lithium-free electrically conductive material is interposed between the object and the lithium-based target material, the grid being electrically connected to the substrate holder.

A processing system for forming an optical coating on a substrate is provided, wherein the optical coating including an anti-reflective coating and an oleophobic coating, the system comprising: a linear transport processing section configured for processing and transporting substrate carriers individually and one at a time in a linear direction; at least one evaporation processing system positioned in the linear transport processing system, the evaporation processing system configured to form the oleophobic coating; a batch processing section configured to transport substrate carriers in unison about an axis; at least one ion beam assisted deposition processing chamber positioned in the batch processing section, the ion beam assisted deposition processing chamber configured to deposit layer of the anti-reflective coating; a plurality of substrate carriers for mounting substrates; and, means for transferring the substrate carriers between the linear transport processing section and the batch processing section without exposing the substrate carrier to atmosphere.