US2304182A - Method of forming metallic films - Google Patents

Description

Dec. 8, 1942. H. M. LANG METHOD OF FORM ING METALLIC FILM Filed June 19, 1939 INVENTOR v fzaraid' 2/427? l 42% /744*% ATTORNEYS Patented Dec. 8, 1942 METHOD OF FORMING METALLIC FILMS Harold Martin Lang, Bronx, N. Y., assignor to Sigmund Colin, New York, N. Y.

Application June 19, 1939, Serial No. 279,932

2 Glaims. (c1. 204-19) This invention relates to improvements in method of forming metallic films.

Its object is to provide a way of making electroplating possible where it otherwise is not. A further object of this invention is to provide a way of forming metallic films upon desired surfaces and rendering such films capable of receiving subsequent electroplates.

More specifically, its object is to provide a preliminary conductive coating to such materials as glass, metals, etc., in such a Way that subsequent deposits of the desired metal or metals may be applied to produce an article having certain desirable characteristics. These characteristics may be greater hardness, greater resistance to tarnish and corrosion, greater or more permanent reflectivity and the desired color, finish or effect.

It is well known that a film of nickel may be deposited upon a desired surface by directing nickel carbonyl in gaseous form against such a surface, heated above the temperature required to decompose the nickel carbonyl. In this manner nickel has been deposited for producing different kinds of surfaces varying from those resembling platinum black to those which are highly polished. It is often desirable to improve the surface of such films or coatings upon the latter type of surfaces by electroplating them, but it has not been possible to do so because during electroplating the tension of the ele'ctroplate causes the nickel film to blister and peel ofi from the surface upon which it has been deposited. I have discovered that this difficulty may be overcome by following the method which I will now describe and that articles of desired novel characteristics may be produced thereby.

The drawing which forms a part of this application is a diagrammatic representation of an apparatus for depositing films of nickel on heated surfaces.

In this drawing, l designates a source of supply of an inert gas, such as carbon dioxide or nitrogen under pressure. ll designates a branched pipe through which the gas may be led through valves l2 and I3 and conduits to a chamber formed by a cover It. The top of the cover may be transparent and, as a convenient way of accomplishing this, it may be formed of clear glass. Around the lower edge of the cover is a gasket I5.

is an electrically heated hot plate having a flat upper surface upon which the gasket l5 is adapted to rest. 2| designates the article, such as a fiat piece of glass, upon which the desired film is to be formed.

I6 is a tube through which gas from the supply tank may be passed through valve l2 directly to the chamber formed by the cover l4. I1 is a U tube, one end of which is connected by a tube W with the end pipe H which is controlled by valve l3 and the other end of which is connected by a tube is with tube I6 which leads to the cover M. v

I will now describe a manner in which this apparatus may be used. With valve l3 closed, a small amount of nickel carbonyl is placed in the U tube, leaving a gas passage over its upper surface, as indicated at 22. The cover M is placed over the glass 2! and the temperature of the hot plate and the glass raised above that required to decompose nickel carbonyl. A temperature of about C. is sufficient for this purpose. During this part of the operation air is expelled from the space surrounding the glass 2|, by allowing inert gas to through valve l2 and conduit I6 into the chamber formed by the cover M, from which it escapes under the gasket I5.

When the desired conditions have been obtained, namely, the glass 2| raised to a temperature of about 150 in a surrounding inert gas, the valve I2 is closed and thevalve I3 opened momentarily. The gas flowing over the liquid nickel carbonyl in the U tube ll forms a carrier for such of the nickel carbonyl which has volatilized and the moment the latter reaches the glass 2! it is decomposed and nickel is deposited on the surface of the glass. According to former practice this operation is continued until the nickel forms an opaque film on the glass and is effective for certain purposes, but it cannot be electroplated for the reason heretofore pointed out.

According to my invention the valve i3 is closed as soon as a thin deposit of nickel has been formed on the glass. This condition may be observed by the operator through the transparent top of the cover it.

This initial nickel deposit is then exposed to air, which is easily accomplished by lifting the cover M from the hot plate 20. This produces a slight degree of oxidation, a barely perceptible change in color being noticed. The oxidized surface thus formed adheres tenaciously to the glass, but is too thin to form an electrode of sufficient conductivity for electroplating at practical current densities.

The cover it is then replaced over the thinly coated glass and the process repeated. More nickel is deposited on the oxidized deposit until a fllm has been formed of suflicient thickness-to serve as the cathode of an electroplating bath. This second deposit usually renders the iilm opaque.

The mirror or metallized article so produced may be used as it is, but to carry the process to completion the object is now transferred, after cooling to room temperature, to an electroplating bath where it is given a deposit of the particular metal desired. Far greater thicknesses of metal can now be applied than is possible without the steps comprising the body of this invention, with out which peeling and blistering of the film from the article result.

I find that carbon dioxide is particularly desirable for use as the carrier gas in the aforesaid apparatus.

As a specific way of using this mthod I apply, rhodium to the treated nickel surface to make the coating whiter, harder, more resistant to corrosion and to increase its reflectivity. In this simple manner a superior front surface mirror may be formed which is suitable for optical instruments, television apparatus and many other uses.

My invention is in no sense limited to the specific use and product described. By using modifications within the spirit and scope of this invention, it is possible to electrolytically deposit many metals onto materials which are non-con! ductive and onto metals which cannot otherwise be electroplated, and I intend no limitations other than those imposed by the following claims.

What I claim is:

1. The herein described method of forming an electrolytically deposited reflecting surface upon a smooth surface of an article upon which an electrodeposit may not be readily formed directly, which comprises heating the surface to a temperature above that required to decompose nickel carbonyl, applying nickel carbonyl in gaseous form to said surface in an inert atmosphere to form a thin primary deposit, oxidizing said primary deposit substantially throughout and sufliciently to form a bond between the surface and the deposit thereon, adding a further deposit of nickel to the oxidized deposit to increase the conductivity of the deposits by again heating the coated surface and applying more nickel carbonyl thereto in an inert atmosphere, and electrolytically adding another metal to the deposits.

2. The herein described method of forming an electrolytically deposited reflecting surface upon a smooth surface of an article upon which an electrodeposit may not be readily formed direct- 1y, which comprises heating the surface to a temperature above that required to decompose nickel carbonyl, applying nickel carbonyl in gaseous form to said surface in an atmosphere of carbon dioxide to form a thin primary deposit, exposing said primary deposit to an oxidizing atmosphere to oxidize said deposit substantially throughout and sufllciently to form a bond between the surface and the deposit thereon, adding a further deposit of nickel to the oxidized deposit to increase the conductivity of the deposits by again heating the coated surface and applying more nickel carbonyl thereto in an atmosphere of carbon dioxide, and electrolytically adding more metal to the deposits 3. The herein described method of forming an electrolytically deposited reflecting surface upon a smooth surface of an article upon which an electrodeposit may not be readily formed directe ly, which comprises heating the surface to a temperature above that required to decompose nickel carbonyl, applying nickel carbonyl in gaseous form to said surface in an inert atmosphere to form a thin primary deposit, oxidizing said primary deposit substantially throughout and sumciently to form a bond between the surface and the deposit thereon, adding a further deposit of nickel to the oxidized deposit to increase the conductivity of the deposits by again heating the coated surface and applying more nickel carbonyl thereto in an inert atmosphere, and electrolytically adding rhodium to the deposits.

HAROLD MARTIN LANG.

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