A method for structuring an anti-counterfeit marking (18) in the thickness of an object (1) made from an at least partially transparent amorphous, semi-crystalline or crystalline material, the at least partially transparent object (1) comprising a top surface (2) and a bottom surface (4) which extends at a distance from the top surface (2).

A method for structuring an anti-counterfeit marking (18) in the thickness of an object (1) made from an at least partially transparent amorphous, semi-crystalline or crystalline material, the at least partially transparent object (1) comprising a top surface (2) and a bottom surface (4) which extends at a distance from the top surface (2).

Methods for making films including a water-soluble polymeric material and a vapor-deposited inorganic coating are disclosed. The method comprises providing a layer of water-soluble polymeric material and vapor depositing an inorganic coating to at least one surface of the layer of water-soluble polymeric material, wherein the inorganic coating comprises a metal oxide. The method further comprises forming a plurality of microfractures extending along the surface of the inorganic coating.

Methods and apparatus for processing a substrate are provided herein. For example, a method for hybrid bonding a wafer comprises performing a first vacuum processing procedure on the wafer disposed within a first processing chamber, obtaining at least one of moisture measurements or organic species measurements within the first processing chamber, comparing the obtained at least one of moisture measurements or organic species measurements with a predetermined threshold, and one of when a comparison of the obtained at least one of moisture measurements or organic species measurements is equal to or less than the predetermined threshold automatically performing a second vacuum processing procedure in a second processing chamber different from the first processing chamber on the wafer, or when the comparison of the obtained at least one of moisture measurements or organic species measurements is greater than the predetermined threshold automatically continuing performing the first vacuum processing procedure on the wafer.

Methods and apparatus for processing a substrate are provided herein. For example, a method for hybrid bonding a wafer comprises performing a first vacuum processing procedure on the wafer disposed within a first processing chamber, obtaining at least one of moisture measurements or organic species measurements within the first processing chamber, comparing the obtained at least one of moisture measurements or organic species measurements with a predetermined threshold, and one of when a comparison of the obtained at least one of moisture measurements or organic species measurements is equal to or less than the predetermined threshold automatically performing a second vacuum processing procedure in a second processing chamber different from the first processing chamber on the wafer, or when the comparison of the obtained at least one of moisture measurements or organic species measurements is greater than the predetermined threshold automatically continuing performing the first vacuum processing procedure on the wafer.

A method for forming films on particles of powder includes diffusing the powder by leading the powder into a jet nozzle and ejecting a jet flow of the powder; leading the diffused particles of powder, a raw material gas, and a reaction gas activated by atmospheric pressure plasma, into a reaction container, and forming a swirl flow in the container; and forming the films on the diffused particles of powder by reaction of a raw material gas and an activated reaction gas in the container. An apparatus is also disclosed having a reaction container with a peripheral wall having a round section in plan view and a jet nozzle for a powder source, raw material gas, and atmospheric pressure plasma sources are coupled to and enter the container at an angle with a radius thereof thereby forming a swirl flow to form a film on the powder.

A CVD apparatus includes a chamber, a susceptor, an entry/takeout port for a substrate, and a gate valve provided at the entry/takeout port, in which the susceptor has a mounting plate and a support, the entry/takeout port is provided on a part of a side of the chamber, and is provided in a range from an inner bottom surface of the chamber to a position corresponding to the lower surface of the mounting plate when the susceptor is located at an upper end in the vertical direction, and the inner bottom surface of the chamber, the range from the inner bottom surface of the chamber to the position corresponding to the lower surface of the mounting plate when the susceptor is located at the upper end in the vertical direction, the lower surface of the mounting plate, and the outer side surface of the support are coated with ceramic liners.

A CVD apparatus includes a chamber, a susceptor, an entry/takeout port for a substrate, and a gate valve provided at the entry/takeout port, in which the susceptor has a mounting plate and a support, the entry/takeout port is provided on a part of a side of the chamber, and is provided in a range from an inner bottom surface of the chamber to a position corresponding to the lower surface of the mounting plate when the susceptor is located at an upper end in the vertical direction, and the inner bottom surface of the chamber, the range from the inner bottom surface of the chamber to the position corresponding to the lower surface of the mounting plate when the susceptor is located at the upper end in the vertical direction, the lower surface of the mounting plate, and the outer side surface of the support are coated with ceramic liners.

A system and method are described for depositing a material onto a receiving surface, where the material is formed by use of a plasma to modify a source material in-transit to the receiving surface. The system comprises a microwave generator electronics stage. The system further includes a microwave applicator stage including a cavity resonator structure. The cavity resonator structure includes an outer conductor, an inner conductor, and a resonator cavity interposed between the outer conductor and the inner conductor. The system also includes a multi-component flow assembly including a laminar flow nozzle providing a shield gas, a zonal flow nozzle providing a functional process gas, and a source material flow nozzle configured to deliver the source material. The source material flow nozzle and zonal flow nozzle facilitate a reaction between the source material and the functional process gas within a plasma region.

A system and method are described for depositing a material onto a receiving surface, where the material is formed by use of a plasma to modify a source material in-transit to the receiving surface. The system comprises a microwave generator electronics stage. The system further includes a microwave applicator stage including a cavity resonator structure. The cavity resonator structure includes an outer conductor, an inner conductor, and a resonator cavity interposed between the outer conductor and the inner conductor. The system also includes a multi-component flow assembly including a laminar flow nozzle providing a shield gas, a zonal flow nozzle providing a functional process gas, and a source material flow nozzle configured to deliver the source material. The source material flow nozzle and zonal flow nozzle facilitate a reaction between the source material and the functional process gas within a plasma region.