A long-range electrochromic fiber for infrared camouflage and preparation method thereof are disclosed. The method includes: coating indium tin oxide dispersion, electrolyte solution, and electrochromic material on the surface of the metal fiber sequentially, and preparing counter electrodes and polymer protective layer on the outside of the electrochromic layer to obtain the long-range electrochromic fiber. The obtained long-range electrochromic fiber can realize the regulation of infrared emissivity, can be continuously prepared for more than 100 meters and has a good application prospect in infrared camouflage, wearable display, etc.

A long-range electrochromic fiber for infrared camouflage and preparation method thereof are disclosed. The method includes: coating indium tin oxide dispersion, electrolyte solution, and electrochromic material on the surface of the metal fiber sequentially, and preparing counter electrodes and polymer protective layer on the outside of the electrochromic layer to obtain the long-range electrochromic fiber. The obtained long-range electrochromic fiber can realize the regulation of infrared emissivity, can be continuously prepared for more than 100 meters and has a good application prospect in infrared camouflage, wearable display, etc.

A device of executing vacuum processing is provided with: a chamber including a single main chamber executing the vacuum processing and being capable of keeping the chamber in a depressurized state; a feeding roller so disposed as to hang down a reinforcement fiber in the main chamber; a winding bobbin winding the reinforcement fiber, the winding bobbin disposed in the chamber horizontally apart from the reinforcement fiber vertically hung down; and a swing body pivotally supported in the chamber to swing about a pivot and including a suspension arm capable of capturing and suspending the reinforcement fiber according to a swing motion of the swing body, the suspension arm is capable of swinging from a first position horizontally apart from the reinforcement fiber vertically hung down, via a second position for capturing the reinforcement fiber, to a third position to suspend the reinforcement fiber above the winding bobbin.

A device of executing vacuum processing is provided with: a chamber including a single main chamber executing the vacuum processing and being capable of keeping the chamber in a depressurized state; a feeding roller so disposed as to hang down a reinforcement fiber in the main chamber; a winding bobbin winding the reinforcement fiber, the winding bobbin disposed in the chamber horizontally apart from the reinforcement fiber vertically hung down; and a swing body pivotally supported in the chamber to swing about a pivot and including a suspension arm capable of capturing and suspending the reinforcement fiber according to a swing motion of the swing body, the suspension arm is capable of swinging from a first position horizontally apart from the reinforcement fiber vertically hung down, via a second position for capturing the reinforcement fiber, to a third position to suspend the reinforcement fiber above the winding bobbin.

Apparatuses, systems and methods associated with substrate assemblies for computer devices are disclosed herein. In embodiments, a core for a substrate assembly includes a first metal region, a second metal region, and a dielectric region located between the first metal region and the second metal region. The dielectric region includes one or more fibers, wherein each of the one or more fibers includes aluminum, boron, silicon, or oxide. Other embodiments may be described and/or claimed.

Apparatuses, systems and methods associated with substrate assemblies for computer devices are disclosed herein. In embodiments, a core for a substrate assembly includes a first metal region, a second metal region, and a dielectric region located between the first metal region and the second metal region. The dielectric region includes one or more fibers, wherein each of the one or more fibers includes aluminum, boron, silicon, or oxide. Other embodiments may be described and/or claimed.

The present disclosure teaches a method of processing chitin, including providing a source of chitin; and pyrolyzing at least a portion of the source of chitin using a microwave plasma. Pyrolyzing includes producing a nanostructured carbon material including at least one of diamond, ultrananocrystalline diamond (UNCD), graphite, and graphene. Pyrolyzing also includes doping the nanostructured carbon material with at least one element selected from the group consisting of nitrogen and boron. Compositions of matter and articles of manufacture are also disclosed.

The present disclosure teaches a method of processing chitin, including providing a source of chitin; and pyrolyzing at least a portion of the source of chitin using a microwave plasma. Pyrolyzing includes producing a nanostructured carbon material including at least one of diamond, ultrananocrystalline diamond (UNCD), graphite, and graphene. Pyrolyzing also includes doping the nanostructured carbon material with at least one element selected from the group consisting of nitrogen and boron. Compositions of matter and articles of manufacture are also disclosed.

The present disclosure relates to textile coatings, and to nanometer sized particles of boron in solution used for textile coatings. In one embodiment, a nano-boron textile coating is comprised of a solution including silicon, a dispersant, a softener, and acetic acid mixed in water; and a plurality of nano-boron particles dispersed in the solution. A textile with an applied nano-boron textile coating, and a process for preparing and applying a textile coating are also disclosed.

The present disclosure relates to textile coatings, and to nanometer sized particles of boron in solution used for textile coatings. In one embodiment, a nano-boron textile coating is comprised of a solution including silicon, a dispersant, a softener, and acetic acid mixed in water; and a plurality of nano-boron particles dispersed in the solution. A textile with an applied nano-boron textile coating, and a process for preparing and applying a textile coating are also disclosed.