Abstract: An oxidizing liquid (20), such as hydrogen peroxide, is vaporized (18) and the vapor is used to deactivate nerve gas, blistering gas, or other biologically active substances such as pathogens, biotoxins, and prions. A second chemical compound (42) in vapor, mist, or fog form is used in conjunction with the oxidizing vapor. In one embodiment, the second chemical preconditions the biologically active substances to be deactivated more efficiently by the oxidizing vapor. In another embodiment, the second chemical boosts the reactivity of the oxidizing vapor. In another embodiment, the other chemical reacts with the oxidizing vapor to form an intermediate compound that deactivates at least some of the biologically active substances.

Abstract: An induction coil (36) generates a magnetic field which induces current in an induction vessel (28). The induction vessel is heated by the current and supplies the heat to a passage (34) within the vessel. A liquid to be vaporized, such as water or hydrogen peroxide solution, is supplied to the passage where it is converted to vapor. The vapor is supplied to a defined area, such as a chamber (14) of a steam or vapor hydrogen peroxide sterilizer (10), where items are microbially decontaminated by the vapor.

Abstract: In one embodiment, the present invention relates to a composite article, comprising a metal foil having a first side and a second side; a protective film of at least one inert silane, titanate or zirconate overlying the first side of the metal foil; and a metal sheet having a first side and a second side, the first side overlying the protective film. In another embodiment, the present invention relates to a method of increasing tarnish resistance of metal foil comprising contacting the metal foil with an inert silane, titanate or zirconate compound to form a protective film having a thickness from about 0.001 microns to about 1 micron on a surface of the metal foil; and attaching the foil to a metal sheet.

Abstract: A method of manufacturing a resistor foil, comprised of a copper layer having a first side and a second side. A tiecoat metal layer having a thickness of between 5 Å and 70 Å is disposed on the first side of the copper layer. A first layer of a first resistor metal having a thickness of between 100 Å and 500 Å is disposed on the tiecoat metal layer, and a second layer of a second resistor metal having a thickness of between 100 Å and 500 Å is disposed on the first layer of the first resistor metal. The first resistor metal has a resistance different from the second resistor metal.

Abstract: In one embodiment, the present invention relates to a method of increasing resin dust resistance of metal foil comprising contacting the metal foil with an inert silane, titanate or zirconate compound to form a resin dust resistant film having a thickness from about 0.001 microns to about 1 micron on a surface of the metal foil. In another embodiment, the present invention relates to a method of treating metal foil comprising contacting a first side of the metal foil with a hydrocarbylsilane solution to form a resin dust resistant film on a surface of the metal foil, the hydrocarbylsilane solution comprising from about 0.01% to about 10% v/v of a hydrocarbylsilane; and laminating a second side of the metal foil to a prepreg.

Abstract: In one embodiment, the present invention relates to a composite article, comprising a metal foil having a first side and a second side; a protective film of at least one inert silane, titanate or zirconate overlying the first side of the metal foil; and a metal sheet having a first side and a second side, the first side overlying the protective film. In another embodiment, the present invention relates to a method of increasing tarnish resistance of metal foil comprising contacting the metal foil with an inert silane, titanate or zirconate compound to form a protective film having a thickness from about 0.001 microns to about 1 micron on a surface of the metal foil; and attaching the foil to a metal sheet.

Abstract: A resistor foil comprised of a layer of copper foil and a coating of an organic molecular semiconductor material on one side of the copper foil.

Abstract: A package for a fiber optic device or fiber optic component having at least one optical fiber extending therefrom. The package is comprised of a support substrate for supporting the optical device or optic component, the support substrate having at least one optical fiber extending therefrom. A housing surrounds the substrate and has an opening at one end. At least one optical fiber extends through the opening. A layer of metal seals the opening of each end of the tube and the glass fiber cladding where the optical fiber extends through the layer of metal. The layer of metal is applied using a thin film deposition process, such as ion-beam assisted deposition, electron-beam deposition, or ion-beam deposition.

Abstract: A package for a fiber optic device or component comprised of an elongated support substrate for supporting an optical device or component having at least one optical fiber extending therefrom. The optical fiber has an inner glass core and a glass cladding surrounded by an outer buffer. An elongated glass tube is dimensioned to receive the support substrate. The glass tube has open ends. The at least one optical fiber extends through one of the open ends with the outer buffer removed from the optical fiber in the vicinity of the open end. A glass seal surrounds the inner glass fiber closing the open ends.

Abstract: A package for a fiber optic device or fiber optic component having at least one optical fiber extending therefrom. The package is comprised of a support substrate for supporting the optical device or optic component, the support substrate having at least one optical fiber extending therefrom. A housing surrounds the substrate and has an opening at one end. At least one optical fiber extends through the opening. A layer of metal seals the opening of each end of the tube and the glass fiber cladding where the optical fiber extends through the layer of metal.

Abstract: A component for use in forming a multi-layer printed circuit comprised of a film substrate formed of a first polymeric material. At least one layer of a flash metal is applied to a first side of the film substrate, and at least one layer of copper is applied on the layer of flash metal. A discrete area of a resistive material is disposed on a second side of the film substrate.

Abstract: A resistor foil, comprised of a copper layer having a first side and a second side. A tiecoat metal layer having a thickness of between 5 Å and 70 Å is disposed on the first side of the copper layer. A first layer of a first resistor metal having a thickness of between 100 Å and 500 Å is disposed on the tiecoat metal layer, and a second layer of a second resistor metal having a thickness of between 100 Å and 500 Å is disposed on the first layer of the first resistor metal. The first resistor metal has a resistance different from the second resistor metal.

Abstract: A resistor foil, comprised of a copper layer having a first side and a second side. An intermediate layer having a thickness of between 5 Å and 70 Å is disposed on the first side of the copper layer. A first layer of a first resistor metal having a thickness of between 50 Å and 2 &mgr;m is disposed on the intermediate layer, and a second layer of a second resistor metal having a thickness of between 50 Å and 2 &mgr;m is disposed on the first layer of the first resistor metal. The first resistor metal has a resistance different from the second resistor metal.

Abstract: A component for use in manufacturing printed circuits that in a finished printed circuit constitutes a functional element. The component is comprised of a film substrate formed of a first polymeric material having a first side and a second side. At least one layer of a tiecoat metal is applied to the first side of the film substrate. At least one layer of copper on the at least one layer of a tiecoat metal, the layer of copper having an essentially uncontaminated exposed surface facing away from the at least one layer of tiecoat metal. A plurality of spaced apart, adhesion promoting areas of a tiecoat metal are provided on the second side of the film substrate defining regions of exposed polymeric material on the second side of the film substrate.

Abstract: A component for use in forming a multi-layer printed circuit comprised of a film substrate formed of a first polymeric material. At least one layer of a flash metal is applied to a first side of the film substrate, and at least one layer of copper is applied on the layer of flash metal. A discrete area of a resistive material is disposed on a second side of the film substrate.

Abstract: A component for use in forming a multi-layer printed circuit comprised of a film substrate formed of a first polymeric material. At least one layer of a flash metal is applied to a first side of the film substrate, and at least one layer of copper is applied on the layer of flash metal. A discrete area of an organic molecular semiconductor material is disposed on a second side of the film substrate.

Abstract: A component for use in manufacturing printed circuits that in a finished printed circuit constitutes a functional element. The component is comprised of a film substrate formed of a first polymeric material having a first side and a second side. At least one layer of a tiecoat metal is applied to the first side of the film substrate. At least one layer of copper on the at least one layer of a tiecoat metal, the layer of copper having an essentially uncontaminated exposed surface facing away from the at least one layer of tiecoat metal. A plurality of spaced apart, adhesion promoting areas of a tiecoat metal are provided on the second side of the film substrate defining regions of exposed polymeric material on the second side of the film substrate.

Abstract: In one embodiment, the present invention relates to a method of increasing resin dust resistance of metal foil comprising contacting the metal foil with an inert silane, titanate or zirconate compound to form a resin dust resistant film having a thickness from about 0.001 microns to about 1 micron on a surface of the metal foil. In another embodiment, the present invention relates to a method of treating metal foil comprising contacting a first side of the metal foil with a hydrocarbylsilane solution to form a resin dust resistant film on a surface of the metal foil, the hydrocarbylsilane solution comprising from about 0.01% to about 10% v/v of a hydrocarbylsilane; and laminating a second side of the metal foil to a prepreg.

Abstract: A component for use in forming a multi-layer printed circuit comprised of a film substrate formed of a first polymeric material. At least one layer of a flash metal is applied to a first side of the film substrate, and at least one layer of copper is applied on the layer of flash metal. A discrete area of a resistive material is disposed on a second side of the film substrate.

Abstract: In one embodiment, the present invention relates to a method of increasing resin dust resistance of metal foil comprising contacting the metal foil with an inert silane, titanate or zirconate compound to form a resin dust resistant film having a thickness from about 0.001 microns to about 1 micron on a surface of the metal foil. In another embodiment, the present invention relates to a method of treating metal foil comprising contacting a first side of the metal foil with a hydrocarbylsilane solution to form a resin dust resistant film on a surface of the metal foil, the hydrocarbylsilane solution comprising from about 0.01% to about 10% v/v of a hydrocarbylsilane; and laminating a second side of the metal foil to a prepreg.