Thermal barrier materials are provided that possess low heat capacity and low thermal conductivity, while at the same time, high structural integrity and robustness. In some embodiments, the disclosed coating comprises metal-containing spheres that are sintered or glued together and/or embedded in a matrix. The coating has at least 60% void volume fraction and closed porosity. The coating thickness is from 50 microns to 500 microns, and the metal spheres have an average diameter that is from about 5% to about 30% of the coating thickness. In some embodiments, the metal spheres have an average diameter that is 4-10 times smaller than the coating thickness. Thermal barrier materials with these coatings can be beneficial in engine applications, for example.

A method for manufacturing a three-dimensional object comprises the steps of (a) bringing at least one nozzle in a first position close to a surface of a substrate, (b) delivering through said at least one nozzle at least one reactant to said surface, (c) effecting a solid forming reaction of said at least one delivered reactant such that said at least one delivered reactant undergoes a transition to become a growing solid deposit on said surface under said at least one nozzle, and (d) detecting an interaction of said growing solid deposit with said at least one nozzle.

A method for manufacturing a three-dimensional object comprises the steps of (a) bringing at least one nozzle in a first position close to a surface of a substrate, (b) delivering through said at least one nozzle at least one reactant to said surface, (c) effecting a solid forming reaction of said at least one delivered reactant such that said at least one delivered reactant undergoes a transition to become a growing solid deposit on said surface under said at least one nozzle, and (d) detecting an interaction of said growing solid deposit with said at least one nozzle.

A method for manufacturing a three-dimensional object comprises the steps of (a) bringing at least one nozzle in a first position close to a surface of a substrate, (b) delivering through said at least one nozzle at least one reactant to said surface, (c) effecting a solid forming reaction of said at least one delivered reactant such that said at least one delivered reactant undergoes a transition to become a growing solid deposit on said surface under said at least one nozzle, and (d) detecting an interaction of said growing solid deposit with said at least one nozzle.

A method for the production of a transparent conductor deposit on a substrate, the method comprising: providing a substrate formed from a first material; depositing a film of a second material on the substrate; causing the film to crack so as to provide a plurality of recesses; depositing a conductive material in the recesses; and removing the film from the substrate so as to yield a transparent conductive deposit on the substrate.

A method for the production of a transparent conductor deposit on a substrate, the method comprising: providing a substrate formed from a first material; depositing a film of a second material on the substrate; causing the film to crack so as to provide a plurality of recesses; depositing a conductive material in the recesses; and removing the film from the substrate so as to yield a transparent conductive deposit on the substrate.

Exemplary embodiments include a method or apparatus for improving the electrolysis efficiency of high-pressure electrolysis cells by decreasing the current density at the anode and reducing an overvoltage at the anode while decreasing the amount of hydrogen permeation through the cell membrane from the cathode chamber to the anode chamber as the high-pressure electrolysis cell is operated.