Disclosed is a degradable film (1) in which a barrier layer (3) is disposed on a surface of a water-soluble polymer layer (2). The water-soluble polymer layer (2) is made of a water-soluble polymer such as polyvinyl alcohol or polyvinyl pyrrolidone. The barrier layer (3) is made of silicon oxide or silicon oxynitride. The barrier layer (3) is formed on the water-soluble polymer layer (2) by a CVD process with the supply of a raw material gas containing a precursor of a substance that forms the barrier layer (3), an ozone gas with an oxygen concentration of 20 vol % or higher and an unsaturated hydrocarbon gas to the water-soluble polymer layer (2).

The invention relates to a nozzle and nozzle head arranged to supply gas towards a surface of a substrate The nozzle comprises a nozzle output surface via which the gas is supplied towards the surface of the substrate, a nozzle top surface opposite the nozzle output surface, and a nozzle side wall extending between the nozzle output surface and the nozzle top surface. The nozzle further comprises at least one recess provided to the nozzle side wall, the at least one recess extending between the nozzle top surface and the nozzle output surface for providing a gas passage from the nozzle top surface to the nozzle output surface when the nozzle side wall is against a counter surface.

A tow coating reactor system includes a reactor for receiving fiber tow, a wedge situated adjacent the reactor and configured to receive the tow at a tip end, such that as the tow moves across the wedge, the wedge spreads the tow into a plurality of sub-tows.

Apparatus for atomic layer deposition on a surface of a substrate includes a precursor injector head. The precursor injector head includes a precursor supply and a deposition space that in use is bounded by the precursor injector head and the substrate surface. The precursor injector head is arranged for injecting a precursor gas from the precursor supply into the deposition space for contacting the substrate surface. The apparatus is arranged for relative motion between the deposition space and the substrate in a plane of the substrate surface. The apparatus is provided with a confining structure arranged for confining the injected precursor gas to the deposition space adjacent to the substrate surface.

A system. The system may include a first zone into which a first precursor is introduced; a second zone into which a second precursor is introduced; a third zone between the first zone and the second zone and in which a reactive species is generated; a fourth zone between the first zone and the third zone; a fifth zone between the second zone and the third zone; wherein a process gas is introduced into the fourth zone and the fifth zone; wherein the reactive species and the first precursor is mixed in the fourth zone and the reactive species and the second precursor is mixed in the fifth zone; and a substrate transport mechanism.

A vapor deposition reactor apparatus, systems and methods for deposition of thin films, particularly high-temperature superconducting (HTS) coated conductors, utilize multi-sided susceptors and susceptor pairs for increased production throughput. The reactors may also be configured in multi-stack arrangements of the susceptors within a single reactor chamber for additional throughput gains.

Systems and method for producing graphene on a substrate are described. Certain types of exemplar systems include lateral arrangements of a substrate gas scavenging environment and an annealing environment. Certain other types of exemplar systems include lateral arrangements of a graphene producing environment and a cooling environment, which cools the graphene produced on the substrate. Yet other types of exemplar systems include lateral arrangements of a localized annealing environment, localized graphene producing environment and a localized cooling environment inside the same enclosure.

Certain type of exemplar methods for producing graphene on a substrate include scavenging a first portion of the substrate and preferably, contemporaneously annealing a second portion of the substrate. Certain other type of exemplar methods for producing graphene include novel annealing techniques and/or implementing temperature profiles and gas flow rate profiles that vary as a function of lateral distance and/or cooling graphene after producing it.

Apparatuses and methods for depositing materials on both sides of a web while it passes a substantially vertical direction are provided. In particular embodiments, a web does not contact any hardware components during the deposition. A web may be supported before and after the deposition chamber but not inside the deposition chamber. At such support points, the web may be exposed to different conditions (e.g., temperature) than during the deposition. Also provided are substrates having materials deposited on both sides that may be fabricated by the methods and apparatuses.

A system for forming surface modified substrates includes a laser system, and a laser processing chamber. A laser scanner automatically controls a position of the laser beam or an x-y translating stage upon which the laser processing chamber is mounted thereon for scanning the laser beam relative to a substrate of material (M) having a bulk portion and an outer surface integrated with the bulk portion, and a coating including metal organic molecules including at least one metal X or particles of metal X on the outer surface. At laser-heated spots atoms of X from the metal coating diffuse into the outer surface to form a modified surface layer including both M and X. The modified surface layer has a thickness of 1 nm, and a 25° C. electrical conductivity ≥2.5% above or ≤2.5% below a 25° C. electrical conductivity in the bulk portion.

An apparatus for manufacturing a polysilicon rod comprising: a core wire 1 on which polysilicon is deposited; a core wire electrode 60 provided to penetrate a bottom plate 80; an adjustment member 10 provided between the silicon core wire 1 and the core wire electrode 60, and movable with respect to the bottom plate 80; and a cooling part capable of cooling the adjustment member 10.