An electrochemical chlorine gas sensor is disclosed with a working electrode, a counter electrode, and a reference electrode. The working electrode may be coated with a nanoporous gold layer, a first solution comprising an ionic liquid, and a second solution that may be selected from a Nafion solution, a chitosan solution, an agar solution, or combinations thereof. The reference and counter electrodes may be further coated with the ionic liquid.

An electrochemical chlorine gas sensor is disclosed with a working electrode, a counter electrode, and a reference electrode. The working electrode may be coated with a nanoporous gold layer, a first solution comprising an ionic liquid, and a second solution that may be selected from a Nafion solution, a chitosan solution, an agar solution, or combinations thereof. The reference and counter electrodes may be further coated with the ionic liquid.

A method for depositing a decorative and/or functional layer on at least a portion of a surface of a finished or semi-finished article made of a non-conductive ceramic material, this deposition method includes the following operations: subjecting the at least a portion of the surface of the article to a carburising or nitriding treatment during which carbon, respectively nitrogen atoms, diffuse in the at least a portion of the surface of the article, then depositing, by galvanic growth of a metallic material, the decorative and/or functional layer on at least a portion of the surface of the article which has undergone the carburising or nitriding treatment.

Provided is a plating film containing Au and Tl, including Tl oxides including Tl.sub.2O on a surface of the plating film, a ratio of Tl atoms constituting Tl.sub.2O to a total of Tl atoms constituting the Tl oxides and Tl atoms constituting Tl simple substances on the surface being 40% or more.

Described is a cathodic treatment for the electrodeposition of a metal layer securely adherent to the surface of stainless steel objects in an electrolytic bath comprising one or more metals belonging exclusively to the groups from 3 to 12 of the periodic table, excluding the elements nickel, cobalt, cadmium, ruthenium, rhodium, palladium, silver, osmium, iridium, platinum, gold and rhenium, and methanesulfonic acid with a concentration of between 100 and 400 g/l. An object of the invention is also a process for applying a metal layer securely adherent to the surface of stainless steel objects, comprising a cathodic treatment as described above. Moreover, the invention further relates to an object comprising stainless steel equipped with a covering obtained by means of a process of the type described.

A method of forming a radio frequency (RF) strap for use in a process chamber is provided. The method includes positioning a core strap including a first material that is electrically and thermally conductive in a first electrochemical bath. The first electrochemical bath includes a first solvent and a first plating precursor. The method further includes forming a first protective coating on an outer surface of the core strap, removing the first solvent and the first plating precursor from the core strap having the first protective coating formed thereon, post-treating the core strap having the first protective coating formed thereon, positioning the core strap having the first protective coating formed thereon in a second electrochemical bath, and forming a second protective coating on an outer surface of the first protective coating. The first protective coating includes nickel, the second electrochemical bath includes a second solvent and a second plating precursor, and the second protective coating includes gold.

A method of forming a radio frequency (RF) strap for use in a process chamber is provided. The method includes positioning a core strap including a first material that is electrically and thermally conductive in a first electrochemical bath. The first electrochemical bath includes a first solvent and a first plating precursor. The method further includes forming a first protective coating on an outer surface of the core strap, removing the first solvent and the first plating precursor from the core strap having the first protective coating formed thereon, post-treating the core strap having the first protective coating formed thereon, positioning the core strap having the first protective coating formed thereon in a second electrochemical bath, and forming a second protective coating on an outer surface of the first protective coating. The first protective coating includes nickel, the second electrochemical bath includes a second solvent and a second plating precursor, and the second protective coating includes gold.

Described is a cathodic treatment for the electrodeposition of a metal layer securely adherent to the surface of stainless steel objects in an electrolytic bath comprising one or more metals belonging exclusively to the groups from 3 to 12 of the periodic table, excluding the elements nickel, cobalt, cadmium, ruthenium, rhodium, palladium, silver, osmium, iridium, platinum, gold and rhenium, and methanesulfonic acid with a concentration of between 100 and 400 g/l.

An object of the invention is also a process for applying a metal layer securely adherent to the surface of stainless steel objects, comprising a cathodic treatment as described above.

Moreover, the invention further relates to an object comprising stainless steel equipped with a covering obtained by means of a process of the type described.

Systems, methods, and devices related to hollow metallic objects are disclosed. A solid sacrificial material is formed in a desired three-dimensional shape, and a precursor is deposited about an exterior surface of the solid sacrificial material. The precursor is used to deposit a first conductor about the exterior surface of the solid sacrificial material, and the solid sacrificial material is then removed. The first conductor assumes the three-dimensional shape, and is substantially hollow after removing the solid sacrificial material. Contemplated hollow metallic objects include waveguides, heat pipes, and vapor chambers.

Provided is a plating film containing Au and Tl, including Tl oxides including Tl.sub.2O on a surface of the plating film, a ratio of Tl atoms constituting Tl.sub.2O to a total of Tl atoms constituting the Tl oxides and Tl atoms constituting Tl simple substances on the surface being 40% or more.