A novel process provides for the preparation of the chlorinated, uncharged substance tetrakis(trichlorosilyl)germane, and for the use thereof.

A novel process provides for the preparation of the chlorinated, uncharged substance tetrakis(trichlorosilyl)germane, and for the use thereof.

A method and system for forming a structure are disclosed. An exemplary method includes providing a substrate comprising a plurality of gaps within a first reaction chamber, forming a doped adhesion film on the surface of a substrate and within the plurality of gaps, wherein the doped adhesion film comprises a first material and a second material, and depositing a metal overlying the doped adhesion film. Exemplary methods can further include a step of depositing a nucleation layer overlying the doped adhesion film. An exemplary system can perform the method of forming the structure.

A method and system for forming a structure are disclosed. An exemplary method includes providing a substrate comprising a plurality of gaps within a first reaction chamber, forming a doped adhesion film on the surface of a substrate and within the plurality of gaps, wherein the doped adhesion film comprises a first material and a second material, and depositing a metal overlying the doped adhesion film. Exemplary methods can further include a step of depositing a nucleation layer overlying the doped adhesion film. An exemplary system can perform the method of forming the structure.

A hybrid protective coating includes an inorganic component and an organic component such that the inorganic component includes at least one of a metal oxide, a metal fluoride, or combination thereof, and the organic component includes at least one metalcone.

A hybrid protective coating includes an inorganic component and an organic component such that the inorganic component includes at least one of a metal oxide, a metal fluoride, or combination thereof, and the organic component includes at least one metalcone.

A method and apparatus for reducing as-deposited and metastable defects relative to amorphous silicon (a-Si) thin films, its alloys and devices fabricated therefrom that include heating an earth shield positioned around a cathode in a parallel plate plasma chemical vapor deposition chamber to control a temperature of a showerhead in the deposition chamber in the range of 350° C. to 600° C. An anode in the deposition chamber is cooled to maintain a temperature in the range of 50° C. to 450° C. at the substrate that is positioned at the anode. In the apparatus, a heater is embedded within the earth shield and a cooling system is embedded within the anode.

The invention relates to a coating method for energetic material (12), in particular in a vacuum. The energetic material (12) is coated by chemical or physical vapor deposition. The coating material (16) is electrically conductive and/or hydrophobic or hydrophilic. The energetic material (12) is shaped as grains and/or pellets and/or is in the form of a powder.

A substrate etching apparatus for etching a substrate, the substrate etching apparatus includes a treatment container configured to accommodate a substrate, a stage on which the substrate is placed, the stage being disposed in the treatment container, a gas supply configured to supply a treatment gas from an upper space above the stage toward the stage, and a gas exhauster configured to evacuate an interior of the treatment container. The gas supply includes a central region facing a central part of the stage and an outer peripheral region having a same central axis as the central region and configured to surround the central region. The gas supply is capable of supplying the treatment gas to each of the central region and the outer peripheral region.

A substrate etching apparatus for etching a substrate, the substrate etching apparatus includes a treatment container configured to accommodate a substrate, a stage on which the substrate is placed, the stage being disposed in the treatment container, a gas supply configured to supply a treatment gas from an upper space above the stage toward the stage, and a gas exhauster configured to evacuate an interior of the treatment container. The gas supply includes a central region facing a central part of the stage and an outer peripheral region having a same central axis as the central region and configured to surround the central region. The gas supply is capable of supplying the treatment gas to each of the central region and the outer peripheral region.