This invention relates to thermal spray coatings and processes onto non-smooth surfaces. The coating and processes can coat non-smooth surfaces without substantial degradation of the underlying surface texture or profile of the non-smooth surfaces so as to sufficiently preserve the underlying surface texture or profile. The ability for coating fractional coverage to maintain the surface profile while maintaining wear resistance is unprecedented by conventional thermal spray processes

A method to increase the damping of a substrate using a face-centered cubic ferromagnetic damping coating.

Multilayer substrates for the growth and/or support of CNT arrays are provided. These multilayer substrates both promote the growth of dense vertically aligned CNT arrays and provide excellent adhesion between the CNTs and metal surfaces. Carbon nanotube arrays formed using multilayer substrates, which exhibit high thermal conductivity and excellent durability, are also provided. These arrays can be used as thermal interface materials.

A turbine component having a face-centered cubic ferromagnetic damping coating with high damping loss attributes applied in a non-molten solid state.

A method to increase the damping of a substrate using a face-centered cubic ferromagnetic damping coating.

A chain element (2), in particular a chain pin (4), for joining at least two chain links (3), characterized in that it comprises a surface layer (5) containing boron and vanadium, formed by at least one step of diffusing boron and vanadium in the areas of the chain element (2) which are close to the surface. The surface layer (5) containing boron and vanadium is formed by boriding and subsequently vanadizing a substrate material having a carbon content of 0.60 wt.-% to 1.0 wt.-%.

A coating composition that contains at least one degradable coating layer and at least one layer of barrier coating is disclosed. The coating composition can be used to make a coated substrate having improved performance over conventional coated substrates after exposure to heat and certain chemicals like halides such as chlorides, sulfur, salt, chlorine, alkali, and enamels.

Armor components having a ceramic substrate, a thermal sprayed barrier coating covering the substrate material to form a barrier coated substrate, and an outermost encapsulation of metal generally surrounding at least the periphery of the barrier coated substrate are disclosed herein. The encapsulation of metal was cast to the ceramic substrate as molten metal, and the thermal sprayed barrier coating comprises a cermet material, a ceramic material, or a combination thereof. The ceramic substrate is preferably a ceramic tile for ballistic armor. Also disclosed are armor components having a plurality of the ceramic tiles interconnected by the encapsulation of metal, with the metal, which was casted thereto, surrounding at least the periphery of each of the plurality of the armor components.

Provided is a thixomolding material including a metal body that contains Mg as a main component, and a coating portion that is adhered to a surface of the metal body via a binder and contains C particles containing C as a main component. A mass fraction of the C particles in a total mass of the metal body and the C particles is 5.0 mass % or more and 40.0 mass % or less. The binder may contain waxes. The C particles may be graphite particles.

A bi-layer protective coating for a metal component, the bi-layer protective coating comprising a bond coating that is metallurgically fused to a substrate of the metal component, wherein the bond coating comprises one or more rare metals and a top coating that is mechanically bonded to the bond coating, wherein the top coating comprises one or more metal oxides, or one or more metal carbides.