The present invention relates to a method of electrodepositing a metal on an electrically conductive particulate substrate. There is provided a method of electrodepositing a metal on an electrically conductive particulate substrate comprising the steps of: (i) providing a cathode; (ii) providing an anode formed from the metal to be electrodeposited; (iii) providing the substrate, cathode and anode within an electrodeposition bath comprising an electrolyte; and (iv) providing a voltage between said anode and cathode causing metal ions to flow from the anode to the cathode, wherein a separator is provided between the anode and the cathode.

A method for microstructure modification of conducting lines is provided. An electroplating process is performed to deposit the metal thin film/conducting line(s) with a face-centered cubic (FCC) structure and a preferred crystallographic orientation over a surface of a substrate. The metal thin film/conducting line(s) is subsequently subjected to a thermal annealing process to modify its microstructure with the grain sizes in a range of 5 μm to 100 μm. The thermal annealing process is conducted at the temperature of above 25 degrees Celsius and below 240 degrees Celsius.

The technology described herein sets forth methods of making low stress or stress free coatings and articles using electrodeposition without the use of stress reducing agents in the deposition process. The articles and coatings can be layered or nanolayered wherein in the microstructure/nanostructure and composition of individual layers can be independently modulated.

The technology described herein sets forth methods of making low stress or stress free coatings and articles using electrodeposition without the use of stress reducing agents in the deposition process. The articles and coatings can be layered or nanolayered wherein in the microstructure/nanostructure and composition of individual layers can be independently modulated.

Articles and methods for depositing iron alloy coatings onto metal wires for wireless recharging devices are generally described.

Articles and methods for depositing iron alloy coatings onto metal wires for wireless recharging devices are generally described.

A cold- or hot-rolled steel strip with a metallic coating, the steel strip having iron as the main constituent and, in addition to carbon, an Mn content of 8.1 to 25.0 wt. % and optionally one or more of the alloying elements Al, Si, Cr, B, Ti, V, Nb and/or Mo. The uncoated steel strip is first cleaned, a layer of pure iron is applied to the cleaned surface, an oxygen-containing, iron-based layer containing more than five mass percent of oxygen is applied to the layer of pure iron. The steel strip is then annealed and is reduction-treated in a reducing furnace atmosphere during the annealing treatment to obtain a surface consisting mainly of metallic iron. The steel strip is then hot-dip coated with the metallic coating. This creates uniform and reproducible bonding conditions for the coating on the steel strip surface.

A cold- or hot-rolled steel strip with a metallic coating, the steel strip having iron as the main constituent and, in addition to carbon, an Mn content of 8.1 to 25.0 wt. % and optionally one or more of the alloying elements Al, Si, Cr, B, Ti, V, Nb and/or Mo. The uncoated steel strip is first cleaned, a layer of pure iron is applied to the cleaned surface, an oxygen-containing, iron-based layer containing more than five mass percent of oxygen is applied to the layer of pure iron. The steel strip is then annealed and is reduction-treated in a reducing furnace atmosphere during the annealing treatment to obtain a surface consisting mainly of metallic iron. The steel strip is then hot-dip coated with the metallic coating. This creates uniform and reproducible bonding conditions for the coating on the steel strip surface.

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

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