A multi-composition fiber is provided including a primary fiber material and an elemental additive material deposited on grain boundaries between adjacent crystalline domains of the primary fiber material. A method of making a multi-composition fiber is also provided, which includes providing a precursor laden environment, and promoting fiber growth using laser heating. The precursor laden environment includes a primary precursor material and an elemental precursor material.

A window member for separating an internal environment of an x-ray device from an environment external to the x-ray device is provided. The window member comprises a substrate and a coating layer disposed upon a surface of the substrate. The substrate is formed from a polycrystalline material and is substantially transparent to low-energy x-rays. The coating layer is non-porous, covers the crystal grains at the surface of the substrate and extends into the grain boundaries therebetween, such that the coating layer forms an impermeable barrier between the substrate and the external environment.

The present invention relates to an information storage medium and a method for long-term storage of information comprising the steps of: providing a ceramic substrate; coating the ceramic substrate with a layer of a second material different from the material of the ceramic substrate, the layer having a thickness no greater than 10 μm; tempering the coated ceramic substrate to form a writable plate or disc; encoding information on the writable plate or disc by using a laser and/or a focused particle beam to manipulate localized areas of the writable plate or disc.

The present invention relates to an information storage medium and a method for long-term storage of information comprising the steps of: providing a ceramic substrate; coating the ceramic substrate with a layer of a second material different from the material of the ceramic substrate, the layer having a thickness no greater than 10 μm; tempering the coated ceramic substrate to form a writable plate or disc; encoding information on the writable plate or disc by using a laser and/or a focused particle beam to manipulate localized areas of the writable plate or disc.

The present disclosure provides a method and system for fabricating a semiconductor device. The method and system of the present disclosure, after obtaining the polysilicon layer, first form the protective oxide layer on the surface of the polysilicon layer, and then etch the protective oxide layer and the protrusions on the surface of the polysilicon layer with the buffered oxide etchant based on controllability of the buffered oxide etchant, thereby reducing the protrusions on the surface of the polysilicon layer, while well protecting the surface of the polysilicon layer. Therefore, the technical problem of surface roughness in the existing polysilicon layers is solved.

The invention relates to a substrate rack and a substrate processing system for processing substrates in a reaction chamber. The substrate rack may be used for introducing a plurality of substrates in the reaction chamber. The substrate rack may have a plurality of spaced apart substrate holding provisions configured to hold the substrates in a spaced apart relationship. The rack may have an illumination system to irradiate radiation with a range from 100 to 500 nanometers onto a top surface of the substrates.

Inside a heating space of a heating chamber, a first heating treatment of moving a substrate along a substrate moving direction is performed by a first conveyor. After that, first conveyance processing of moving the substrate along a conveying direction is performed by a second conveyor. At this time, source mist is sprayed on the substrate by first thin film forming nozzles. Subsequently, second heating treatment is performed by a third conveyor. After that, second conveyance processing is performed by a fourth conveyor. At this time, source mist is sprayed on the substrate by second thin film forming nozzles.

A method of forming a high purity granular material, such as silicon carbide powder. Precursors are added to a reactor; at least part of a fiber is formed in the reactor from the precursors using chemical deposition interacting with said precursors; and the granular material is then formed from the fiber. In one aspect, the chemical deposition may include laser induced chemical vapor deposition. The granular material may be formed by grinding or milling the fiber into the granular material, e.g., ball milling the fiber. In one example, silicon carbide powder having greater than 90% beta crystalline phase purity and less than 0.25% oxygen contamination can be obtained.

The invention includes apparatus and methods for instantiating and quantum printing materials, such as elemental metals, in a nanoporous carbon powder.

The invention includes apparatus and methods for instantiating and quantum printing materials, such as elemental metals, in a nanoporous carbon powder.