Abstract: Described herein are electrodeposited corrosion-resistant multilayer coating and claddings that comprises multiple nanoscale layers that periodically vary in electrodeposited species or electrodeposited microstructures. The coatings may comprise electrodeposited metals, ceramics, polymers or combinations thereof. Also described herein are methods for preparation of the coatings and claddings.

Abstract: This disclosure includes coatings for increasing the physical and/or chemical properties of articles, for example, tubular metal articles such as those found in the oil and gas industry, as well as processes for making such coatings and articles comprising such coatings.

Abstract: Described herein are apparatus and methods for the continuous application of nanolaminated materials by electrodeposition.

Abstract: Described herein are electrodeposited corrosion-resistant multilayer coating and claddings that comprises multiple nanoscale layers that periodically vary in electrodeposited species or electrodeposited microstructures. The coatings may comprise electrodeposited metals, ceramics, polymers or combinations thereof. Also described herein are methods for preparation of the coatings and claddings.

Abstract: Described herein are apparatus and methods for the continuous application of nanolaminated materials by electrodeposition.

Abstract: An armor material and method of manufacturing utilize nano- and/or microlaminate materials. In one embodiment, the armor material comprises a layered composite material including a strike face, a core layer, and a spall liner. The strike face achieves hardness and toughness by the controlled placement of hard and tough constituent materials through the use of nano- and/or microlaminate materials. The core layer achieves energy absorption through the use of nano- or microlaminated coated compliant materials. The spall liner provides reinforcement through the use of nano- or microlaminated fiber reinforced panels. In one embodiment, nano- and/or microlaminated materials can be manufactured through the use of electrodeposition techniques.

Abstract: Described herein are electrodeposited corrosion-resistant multilayer coating and claddings that comprises multiple nanoscale layers that periodically vary in electrodeposited species or electrodeposited microstructures. The coatings may comprise electrodeposited metals, ceramics, polymers or combinations thereof. Also described herein are methods for preparation of the coatings and claddings.

Abstract: This disclosure includes coatings for increasing the physical and/or chemical properties of articles, for example, tubular metal articles such as those found in the oil and gas industry, as well as processes for making such coatings and articles comprising such coatings.

Abstract: Described herein are apparatus and methods for the continuous application of nanolaminated materials by electrodeposition.

Abstract: Articles prepared by additive manufacturing of preforms that are coated by electrodeposition of nanolaminate materials, and methods of their production are described.

Abstract: The present disclosure describes functionally graded coatings and claddings for corrosion and high temperature protection.

Abstract: An improved fuel tank and method of forming a fuel tank utilize reinforced porous metal composite materials. In one embodiment, the composite material includes a fully dense, fluid-impermeable skin combined with a porous metal baffle. The skin and baffle may be formed as a single monolithic system via electrodeposition of a nanolaminate material into at least a portion of open, accessible void space within a porous preform (e.g., a metal foam preform) and on the exterior surface of the preform to form the fluid-impermeable skin.

Abstract: The present disclosure describes functionally graded coatings and claddings for corrosion and high temperature protection.

Abstract: This disclosure provides novel compositions comprising an inorganic and organic compound, which provides a means for the indirect attachment of a reactive species, such as an organic reactive molecule, within a binder polymer matrix. Such compositions provide a hydrophilic nanoscale domain that is uniformly dispersed within the polymer matrix. The nanoscale domain comprises inorganic particles having a nanoscale dimension. Such compositions can enhance the performance potential of the re-active species within the polymer material. The polymer composite that results from the introduction of such reactive species into a polymer matrix provides a self-decontaminating feature. The reactive species include those that are capable of associating with a halogen to form a complex that is active in decontamination of chemical or biological agents.

Abstract: Described herein are electrodeposited corrosion-resistant multilayer coating and claddings that comprises multiple nanoscale layers that periodically vary in electrodeposited species or electrodeposited microstructures. The coatings may comprise electrodeposited metals, ceramics, polymers or combinations thereof. Also described herein are methods for preparation of the coatings and claddings.

Abstract: An improved fuel tank and method of forming a fuel tank utilize reinforced porous metal composite materials. In one embodiment, the composite material includes a fully dense, fluid-impermeable skin (1) combined with a porous metal baffle (2). The skin (1) and baffle (2) may be formed as a single monolithic system via electrodeposition of a nanolaminate material into at least a portion of open, accessible void space within a porous preform (e.g., a metal foam preform) and on the exterior surface of the preform to form the fluid-impermeable skin (1).

Abstract: An armor material and method of manufacturing utilize nano- and/or microlaminate materials. In one embodiment, the armor material comprises a layered composite material including a strike face, a core layer, and a spall liner. The strike face achieves hardness and toughness by the controlled placement of hard and tough constituent materials through the use of nano- and/or microlaminate materials. The core layer achieves energy absorption through the use of nano- or microlaminated coated compliant materials. The spall liner provides reinforcement through the use of nano- or microlaminated fiber reinforced panels. In one embodiment, nano- and/or microlaminated materials can be manufactured through the use of electrodeposition techniques.

Abstract: This disclosure provides novel compositions comprising an inorganic and organic compound, which provides a means for the indirect attachment of a reactive species, such as an organic reactive molecule, within a binder polymer matrix. Such compositions provide a hydrophilic nanoscale domain that is uniformly dispersed within the polymer matrix. The nanoscale domain comprises inorganic particles having a nanoscale dimension. Such compositions can enhance the performance potential of the re-active species within the polymer material. The polymer composite that results from the introduction of such reactive species into a polymer matrix provides a self-decontaminating feature. The reactive species include those that are capable of associating with a halogen to form a complex that is active in decontamination of chemical or biological agents.