Ceramic metallic coatings

The invention claimed is: 1 . A treated and coated part of an automotive trim piece, comprising: a plastic substrate having a glow-discharged surface; a base layer adhered to the plastic substrate, wherein the base layer is a composition material of titanium, aluminum or copper; a magnetron sputtered coating adhered to the base layer, wherein the magnetron sputtered coating is a chemically-reactive, non-stoichiometric, ceramic metal coating; and the treated and coated part of the automotive trim piece is produced by a process of: presenting an uncoated part of the automotive trim piece for treatment and coating; placing the uncoated part of the automotive trim piece in a vacuum chamber of a magnetron sputtering apparatus; operating the magnetron sputtering apparatus in a process that is configured to produce the treated and coated part of the automotive trim piece based on a composition of said base layer, a composition of said chemically-reactive, non-stoichiometric, ceramic metal coating of a number of sputtered targets and a composition of a sputtering reactive gas, where the number of sputtered targets includes at least one material of titanium or aluminum or copper; and controlling a number of process parameters of the magnetron sputtering apparatus selected from a group of said process parameters including: power levels operating at 20 kW-60 kW, processing times, a reactive gas component, a concentration of Argon process gas; which are configured to provide a resultant color of the automotive trim piece from a chemical reaction between reactants of said number of sputtered targets and reactants of the sputtering reactive gas; omitting or applying a protective coating that adheres to the magnetron sputtered coating; the treated and coated part of the automotive trim piece yields a predetermined color and metallic appearance of the magnetron sputtered coating deposited onto the automotive trim piece. 2 . The treated and coated part of an automotive trim piece of claim 1 , wherein the plastic substrate includes an automotive bezel or an automotive trim piece. 3 . The treated and coated part of an automotive trim piece of claim 1 , wherein the plastic substrate includes an automotive lamp bezel or an automotive lamp trim piece. 4 . The treated and coated part of an automotive trim piece of claim 1 , wherein the plastic substrate includes one of polycarbonate and high-temperature polycarbonate. 5 . The treated and coated part of an automotive trim piece of claim 1 , wherein the protective coating includes one of hexymethyldisiloxane (HMDSO) and tetramethyldisiloxane (TMDSO). 6 . The treated and coated part of an automotive trim piece of claim 1 , wherein the base layer is approximately 20-100 nm thick. 7 . The treated and coated part of an automotive trim piece of claim 1 , wherein the protective coating forms a topcoat of the treated and coated part of an automotive trim piece. 8 . The treated and coated part of an automotive trim piece of claim 1 , wherein the sputtering reactive gas includes one of nitrogen, acetylene or a combination of nitrogen and acetylene. 9 . The treated and coated part of an automotive trim piece of claim 1 , wherein the base layer includes an alternate composition material that is distinguished from the composition material that includes silver, nickel or steel. 10 . A treated and coated part of an automotive trim piece, comprising: a plastic substrate having a glow-discharged surface; a base layer adhered to the plastic substrate, wherein the base layer is a composition of titanium, aluminum or copper; a magnetron sputtered coating adhered to the base layer, wherein the magnetron sputtered coating is a chemically-reactive, non-stoichiometric, ceramic metal coating; and the treated and coated part of the automotive trim piece produced by a process of: presenting an uncoated part of the automotive trim piece for treatment and coating; placing the uncoated part of the automotive trim piece in a vacuum chamber of the magnetron sputtering apparatus; operating the magnetron sputtering apparatus in a process that is configured to produce the treated and coated part of the automotive trim piece based on a composition of said base layer, a composition of said chemically-reactive, non-stoichiometric, ceramic metal coating of a number of sputtered targets and a composition of a sputtering reactive gas, where the number of sputtered targets includes at least one material of titanium or aluminum or copper; and controlling a number of process parameters of the magnetron sputtering apparatus selected from a group of said process parameters including: power levels between 20 kW-60 kW, processing times, a reactive gas component, a concentration of Argon process gas; which are configured to provide a resultant color of the automotive trim piece from a chemical reaction between reactants of said number of sputtered targets and reactants of the sputtering reactive gas; applying a protective coating that adheres to the magnetron sputtered coating; the treated and coated part of the automotive trim piece yields a predetermined color and metallic appearance of the magnetron sputtered coating deposited onto the automotive trim piece.