Patent Publication Number: US-5250363-A

Title: Chromium-zinc anti-tarnish coating for copper foil having a dark color

Description:
CROSS-REFERENCED TO RELATED APPLICATION 
     This Application is a Continuation-in-Part of U.S. patent application Ser. No. 07/855,380, filed Mar. 20, 1992 which is a Continuation-in-Part of U.S. patent application Ser. No. 07/673,923 filed Mar. 25, 1991 which is now U.S. Pat. No. 5,098,796, which in turn is a Division of U.S. patent application Ser. No. 07/585,832, filed Sep. 20, 1990 which is now U.S. Pat. No. 5,022,968, which is a Continuation-in-Part of U.S. patent application Ser. No. 07/459,846 filed Jan. 2, 1990 (now abandoned) which in turn is a Continuation in Part of U.S. patent application Ser. No. 07/421,475 filed Oct. 13, 1989 (now abandoned). 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention broadly relates to a method for treating copper and copper base alloy materials to form a tarnish and oxidation resistant film. More particularly, the invention relates to an electrolyte and an electrolytic means for depositing a nontransparent chromium-zinc film on a copper or copper base alloy foil. 
     Copper and copper base alloy foils are widely used in the printed circuit board industry. The foil is produced to a thickness of under 0.15 mm 0.006 inches) and more generally to a thickness in the range of from about 0.005 mm (0.0002 inches and known in the art as 1/8 ounce foil) to about 0.071 mm (0.0028 inches and known in the art as 2 ounce copper foil). The foil is produced by one of two means. &#34;Wrought&#34;  foil is produced by mechanically reducing the thickness of a copper or copper alloy strip by a process such as rolling. &#34;Electrodeposited&#34; foil is produced by electrolytically depositing copper ions on a rotating cathode drum and then peeling the deposited strip from the cathode. 
     The foil is then bonded to a dielectric support layer forming a printed circuit board. The dielectric support layer is typically a polyimide such as Kapton manufactured by DuPont or FR-4 (a fire retardant epoxy). The copper foil layer is laminated to the dielectric carrier layer. Lamination comprises bonding the copper foil layer to the dielectric carrier layer through the use of heat and pressure. A pressure of about 2.1 MPa (300 psi), at a temperature at about 175° C. for a time of up to 30 minutes will provide suitable adhesion between the layers. 
     To maximize adhesion, it is desirable to roughen the surface of the foil which contacts the dielectric prior to bonding. While there are a variety of techniques available to roughen or treat the foil, one exemplary technique involves the formation of a plurality of copper or copper oxide dendrites on the foil surface. U.S. Pat. Nos. 4,468,293 and 4,515,671, both to Polan et al disclose this treatment. The process produces COPPERBOND® foil (COPPERBOND® is a trademark of Olin Corporation, Stamford, Conn.). 
     One problem facing printed circuit board manufacturers using either electrolytic or wrought copper foils is the relative reactivity of the copper. Copper readily stains and tarnishes. Tarnishing may occur during room temperature storage of the foil or during elevated temperature lamination. The stains and tarnish are aesthetically unpleasant and may be a source of problems during the manufacture of the printed circuit board. For example, staining of copper foil prior to lamination can affect both the bond strength between the foil and the dielectric substrate and the etching characteristics of the resultant laminate. 
     In the past, stain resistance has been imparted to copper and copper base alloy materials by immersion in an electrolyte containing chromate ions. U.S. Pat. No. 3,625,844 to McKean, describes a method of stain-proofing copper foil involving the electrolytic treatment of the foil in a aqueous electrolyte under critical conditions of hexavalent chromium ion concentration, cathode current density, and treatment time. 
     U.S. Pat. N. 3,853,716 to Yates et al, discusses the McKean process and points out that it is not a completely satisfactory stain-proofing technique, due to a build-up of copper and chromium cations in the electrolyte bath. The cations interfere with the effectiveness of the stain proofing. Yates et al attempt to overcome this problem by rendering the copper material cathodic as it passes through an aqueous electrolyte containing hexavalent chromium ion containing anions and being of sufficient alkalinity to cause precipitation of copper and chromium cations. 
     U.S. Pat. No. 4,387,006 to Kajiwara et al discloses coating a copper foil with zinc chromate to prevent a reaction between the hardener added to an epoxy-glass substrate and the foil. The coating is deposited from an aqueous solution containing in excess of 1.0 g/l of both zinc and chromium (VI) ions. 
     Still other stain proofing techniques are illustrated in United Kingdom published patent applications 2,030,176A and 2,073,779A and U.S. Pat. No. 4,131,517 to Matsuo et al. 
     Solutions of phosphoric acid, chromic acid and/or their salts have also been applied to various materials in an attempt to impart tarnish and corrosion resistance. U.S. Pat. Nos. 3,677,828, 3,716,427 and 3,764,400, all to Caule, illustrate the use of phosphoric acid solutions to improve the tarnish resistance of copper and copper-based alloys. Caule also describes in his &#39;400 patent the use of a caustic rinse solution after application of his phosphoric acid treatment. U.S. Pat. No. 4,647,315 to Parthasarathi et al, discloses a dilute aqueous chromic acid-phosphoric acid solution. 
     Phosphoric and/or chromic acid solutions have also been applied to zinc, zinc-coated articles and aluminum foil and articles. U.S. Pat. Nos. 2,030,601 to McDonald, 2,412,532 to Tanner, 2,418,608 to Thompson et al, 2,647,865 to Freud and 4,432,846 to Honnycutt, III, illustrate some of the applications of phosphoric-chromic acid solution. 
     Following lamination, the anti-tarnish coating must be removed so the underlying copper foil may be etched into a desired circuit pattern. Circuit traces are patterned into the copper foil by photolithography as known in the art. The unbonded side of the copper foil is coated with a photo-sensitive chemical resist. The resist is exposed to a developer such as ultraviolet light exposed through a mask containing the desired circuit pattern. Dependent on whether the photoresist is that known in the art as &#34;positive&#34; resist or &#34;negative&#34; resist, the image may be either a desired circuit pattern, or the negative image. After exposure, the unexposed portion of the photoresist is removed by rinsing with an appropriate solvent to expose the underlying foil. The circuit board is then immersed in a suitable etchant to remove the exposed copper. After etching and rinsing, the remaining photoresist is removed by a solvent wash. The dielectric substrate is unaffected by the solvent and etchant. The substrate remains intact and the copper foil layer is patterned into a desired configuration of circuit traces. 
     If the anti-tarnish coating layer is not completely removed, it may interfere with the etching step during photolithography resulting in incomplete etching and the potential for an electrical short circuit. One chemical solution used to remove the anti-tarnish coating comprises 4% by volume hydrochloric acid in water. Many of the prior art anti-tarnish coatings are not readily removed by the 4% HCl solution and require mechanical abrasion or other invasive techniques. Partial removal of the coating layer or an inordinately long process time may result. 
     While generally used as the etchant to remove the anti-tarnish coating from copper foil, hydrochloric acid is not desirable for environmental reasons. The chloride ions present are environmentally damaging. Regeneration of the ions into a reusable etchant or the safe disposal of the ions is an expensive proposition. A preferred solution would be to provide an anti-tarnish coating which is readily removed by a less harmful etchant. 
     It is known in the art that a chromium-zinc compound forms a satisfactory anti-tarnish coating for copper and copper base alloys. One such commercial coating has the composition 10 atomic % Zn; 5% Cr; 37% O; 46% C and 2% Cu. The coating is readily removed with a 4% HCl solution. However, the coating is not removable by other, more preferred etchants such as H 2  SO 4 . 
     SUMMARY OF THE INVENTION 
     Accordingly, it is an object of the present invention to provide an electrolytic solution capable of depositing a chromium-zinc compound on the surface of a copper or copper alloy foil. It is a further object of the invention to provide a method for electrolytic deposition such that a high through-put rate and controlled compound composition may be achieved. Yet another object of the invention is to selectively alter the transparency of the anti-tarnish coating. 
     It is an advantage of the present invention that the coating layer so deposited has good tarnish resistance to both roughened foil surfaces as well as smooth foil surfaces. It is a further advantage of the invention that the coating layer is readily removed by a 4% HCl solution. Yet another advantage of the invention is the coating layer so produced is readily removed in a dilute sulfuric acid solution. 
     Another advantage of the invention is that the anti-tarnish coating may be imparted with a color when deposited on wrought foil and transparency when deposited on electrodeposited foil to facilitate identification of the foil type. Alternatively, one side of a copper foil substrate may be coated with a nontransparent anti-tarnish coating while the opposite side is coated with a transparent coating. Further, an anti-tarnish coating layer with a relatively high zinc content may be deposited on the side of the foil to be laminated to a polymer substrate in printed circuit manufacture. The higher zinc content coating withstands elevated temperature exposure without a loss of adhesion better than lower zinc content coating layers. 
     It is a feature of the invention that in one embodiment a caustic rinse solution is provided which further improves the tarnish resistance of the coating when applied to a roughened surface. 
     In accordance with the present invention, there is a provided a composite material made up of a metallic substrate having first and second sides. A first anti-tarnish coating is deposited on at least the first side of the metallic substrate. The first anti-tarnish coating is nontransparent and is formed from a codeposited layer of zinc and chromium having a zinc to chromium ratio in excess of about 13 to 1. The objects, features and advantages discussed above will become more apparent from the specification and drawing which follow. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates an electrolytic cell for depositing a chromium-zinc anti-tarnish coating according to the method of the invention. 
     FIG. 2 illustrates in cross-sectional representation a metallic foil coated with the anti-tarnish coating of the invention. 
     FIG. 3 illustrates a metallic substrate laminated to an a dielectric substrate in accordance with the manufacture of a printed circuit board. 
     FIG. 4 illustrates an intermediate step in the manufacture of a printed circuit board. 
     FIG. 5 illustrates a printed circuit board which was formed utilizing the anti-tarnish coatings of the invention. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1 illustrates an electrolytic cell 10 for depositing an anti-tarnish coating on at least one surface of a metallic substrate 12 according to the invention. While the substrate 12 may be any electrically conductive metal or metal alloy, to maximize electrical conductivity, copper and copper alloys are preferred. The substrate may be any shape, such as a sheet, foil, rod or discrete component. Typically, the substrate 12 is a foil for use in printed circuit boards. The electrolytic cell 10 comprises a tank 14 manufactured from any material which does not react with the electrolyte solution 16. An exemplary material for tank 14 is a polymer, such as polyethylene or polypropylene. Additional elements of the electrolytic cell include the electrolyte, first and second anodes in spaced relationship to one another, and a power supply. 
     Guide rolls 18 control the travel of the foil strip 12 through the electrolytic cell 10. The guide rolls 18 are manufactured from any material which does not react with the electrolyte solution 16. Preferably, at least one of the guide rolls is formed from an electrically conductive material, such as stainless steel, so that a current may be impressed in the foil strip 12. Guide rolls 18 rotate at a controlled speed so that the foil strip 12 is passed between the anodes 20, 21 for a required time. 
     At least one power source (not shown) provides an electric current through the anodes 20, 21 to the foil strip (cathode) 12 by means of the electrolyte solution 16. In this way, an anti-tarnish coating with the desired composition and thickness is deposited on the foil strip 12. 
     The current passing through the two anodes 20, 21 need not be equivalent. There is a critical ratio of zinc to chromium above which the deposited coating is not transparent. One method of increasing the zinc content is by increasing the current density impressed on the surface of the strip. The current passing through the first anode 20 could be above that necessary to impart a nontransparent coating of a first surface 22 of the foil strip 12. The current passing through the second anode 21 could be zero, in which case no coating is applied to the second surface 24 of the foil strip 12. Alternatively, the current passing through the second anode 21 could be sufficiently low such that a transparent coating layer is deposited on the second surface. As a second alternative, the second anode 21 could pass a sufficiently high current to deposit a nontransparent coating on the second surface 24 of the foil strip 12. 
     FIG. 2 illustrates a composite material 25 in cross sectional representation according to a preferred embodiment of the invention. The composite material has a metallic substrate 12 such as a copper or a copper base alloy foil containing a plurality of dendrites 26 on at least a first surface 22. The dendrites 26 are usually formed by electrolytic deposition as more fully described in U.S. Pat. Nos. 4,488,293 and 4,515,671, both of which are incorporated by reference herein in their entireties. 
     A first anti-tarnish layer 28 is deposited on the first surface 22 coating the plurality of dendrites 26, if present. The first anti-tarnish layer is not transparent and is preferably a dark color such as olive green, grey or black. 
     The dark color anti-tarnish coating can be utilized to identify the foil as wrought. The dark coating is not deteriorated by heating to 230° C. for in excess 30 minutes. This is an improvement over zinc coatings which do not contain chromium. The zinc coatings turn yellow following thermal exposure indicating a chemical reaction between the copper substrate and the zinc layer to form brass. Brass created in this manner is not desirable because it is susceptible to undercutting during the etching of fine line circuit patterns. The presence of chromium in the anti-tarnish coatings of the invention either retards the formation of this type of brass or combines with the copper substrate to form a unique ternary alloy. In the manufacture of a printed circuit board, the first surface 22 of the metallic foil 12 is laminated to a dielectric substrate at elevated temperatures. It is highly desirable that brass not form during lamination. 
     The second surface 24 is preferably coated with a second anti-tarnish layer 30. The second anti-tarnish layer 30 is preferably transparent for both cosmetic reasons, the copper color of the metallic substrate 12 remains visible, and to identify the smooth (non-dendritic) surface of the foil. Further, the transparent coating is easier to remove in dilute acids improving the photolithographic process. 
     The electrolytic solution of electrolyte 16 consists essentially of a hydroxide source, zinc ion source and a water soluble hexavalent chromium. The hydroxide source is preferably sodium hydroxide or potassium hydroxide, and most preferably, sodium hydroxide (NaOH). The hexavalent chromium source may be any water soluble hexavalent chromium compound such as Na 2  Cr 2  O 7 .2H 2  O. 
     In its broadest compositional range, the electrolyte solution 16 consists essentially of from about 5 to about 100 grams per liter of the hydroxide, from 0.07 to about 7 grams per liter of zinc ions supplied in the form of a water soluble zinc compound such as ZnO and from 0.1 to about 100 grams per liter of a water soluble hexavalent chromium salt. Provided, however, that at least one of the zinc ion or chromium (VI) ion concentrations is less than 1.0 gm/l. In a preferred embodiment, the electrolyte contains from about 10 to about 25 grams per liter NaOH, from about 0.16 to about 1.2 gm/l zinc ions, most preferably in the form of 0.2 to about 1.5 grams per liter ZnO and from about 0.08 to about 0.78 gm/l Cr (VI) ions most preferably in the form of from about 0.2 to about 2 grams per liter sodium dichromate. 
     With each of the solutions described herein above, it is believed that an effective concentration of a surfactant such as lauryl sulfate will provide a more uniform surface. 
     The pH of the solution is maintained as basic. A pH in the range of from about 12 to 14 is preferred. 
     The solution temperature influences the color of the deposit as does the current density. Any temperature from about 0° C. to about 100° C. can be used with a corresponding current density to produce a suitable nontransparent coating. A preferred temperature range is from about 50° C. to about 90° C. The most preferred temperature range is from about 60° C. to about 80° C. Some suitable exemplary values are apparent from Table 1. 
     
                       TABLE 1                                                     
______________________________________                                    
Current Density                                                           
             Temperature (°F.)                                     
                            Color                                         
______________________________________                                    
30 mA/cm.sup.2                                                            
             160            Gray                                          
30 mA/cm.sup.2                                                            
             130            Patchy gray                                   
15 mA/cm.sup.2                                                            
             130            Gray tinge                                    
 8 mA/cm.sup.2                                                            
             130            Transparent                                   
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     While preferred temperature and current parameters are selected on a run by run basis, generally temperatures above 140° F. and current densities above 15 mA/cm 2  will produce a gray colored coating layer. Lower temperatures and/or lower current densities result in a more transparent coating. 
     In one preferred embodiment, the electrolyte 16 is at 54° C., the first anode 20 impresses a current density of 30 mA/cm 2  on the first surface 22 and the second anode 21 impresses a current density of 8 mA/cm 2  on the second surface 24. The foil substrate is coated on the first surface 22 with a gray anti-tarnish layer and on the second surface 24 with a transparent anti-tarnish coating. 
     The electrolyte solution operates well in a wide range of current densities. Successful coatings may be applied with a current density ranging from 1 milliamp per square centimeter up to about 1 amp per square centimeter. A more preferred current density is from about 3 mA/cm 2  to about 100 mA/cm 2 . The current density employed determines the thickness and the color of the anti-tarnish coating. Generally, a current density in excess of about 20 mA/cm 2   produces a nontransparent coating layer. The preferred current density for the nontransparent coating layers is from about 30 to about 50 mA/cm 2 . Below about 15 mA/cm 2 , the coating layer is usually transparent. The preferred current density range for depositing the transparent coating layers is from about 3 to about 10 mA/cm 2 . 
     Thickness is dependent on the dwell time, the time the foil strip 12 is between the anodes 20 and immersed in electrolyte solution 16. Typically, this dwell time is from about 10 to about 25 seconds. During this dwell time an effective thickness of the anti-tarnish coating compound is deposited. The effective thickness is that capable of inhibiting copper tarnish at elevated temperatures of up to about 180° C. in air for about 30 minutes. The anti-tarnish coating should further be sufficiently thin to be easily removable with a 4% HCl etch solution or preferably a 5wt% H 2  SO 4  etch solution. It is believed that an effective coating thickness is from less than 100 angstroms to about 0.1 microns. Successful results have been obtained with coating thicknesses as low as 40 angstroms and coating thicknesses of from about 10 angstroms to about 100 angstroms are preferred. The coating layer is sufficiently thin to appear transparent or impart a slight gray tinge to the copper foil. 
     The ratio of Zn to Cr (VI) ions, the current density and the temperature all influence the composition of the deposited coating. While the ratio of Zn ions to Cr (VI) ions in solution has an obvious influence on the composition of the coating, temperature also plays a significant role. The higher the temperature, the higher the zinc to chromium ratio for a given electrolyte solution. For example, an electrolyte containing 0.99 grams per liter of Zn (VI) ions and 0.2 grams per liter Cr (VI) ions at a current density of 8 mA/cm 2  deposited a coating having a zinc to chromium ratio of 7.2 at 130° F. The same electrolyte and current density at a temperature of 71° C. (160° F.) produced a coating having a zinc to chromium ratio of 13.8. 
     The zinc to chromium ratio should be maintained at in excess of about 4:1. More preferably, for a transparent coating, the zinc to chromium ratio should be in the range of from about 5:1 to about 12:1 and most preferably, in the range of about 6:1 to about 10:1. For a nontransparent coating such as a grey color, the zinc to chromium ratio should be in excess of about 13:1 and more preferably from about 13:1 to about 18:1. In preferred aspects of the invention, sufficient chromium should be present to promote the formation of a copper-chromium-zinc alloy which minimizes undercutting during photolithography. Additionally, the presence of chromium inhibits the dissolution of the deposited anti-tarnish coating in the electrolyte drag-out prior to rinsing. 
     The preferred coatings of the invention are cosmetically acceptable, are either transparent or have a uniform, non-mottled color, readily withstand a bake test and are easily removed in dilute sulfuric acid. 
     The coated foil strip 12 exits the electrolytic cell 10 and excess electrolyte is rinsed from the surfaces of the strip. The rinse solution may comprise deionized water. More preferably, a small quantity of a caustic is added to the deionized water rinse solution. The concentration of caustic is quite low, under 1 percent. Preferably the caustic concentration is from about 50 to about 150 parts per million. The caustic is selected to be the hydroxide of an alkali metal or the hydroxide of an alkaline earth metal selected from the group consisting of sodium hydroxide, calcium hydroxide, potassium hydroxide and ammonium hydroxide. Most preferred is calcium hydroxide. 
     A small amount of an organic silane, such as C 8  H 22  N 2  O 3  Si, on the order of about 1 milliliter per liter, may also be added to the rinse solution to maintain peel strength. 
     After rinsing, the foil strip is dried by forced air. The air may be cool, that is at room temperature or heated. Heated forced air is preferred since accelerated drying minimizes spotting of the foil. 
     One application of a copper foil coated with the anti-tarnish coatings of the invention is illustrated in FIGS. 3-5. FIG. 3 shows in cross sectional representation a metallic substrate 12 such as a copper foil which has a plurality of dendrites 26 formed on a first surface 22 of the substrate. A first anti-tarnish coating 28 having a zinc to chromium ratio in excess of about 13:1 is deposited onto the first surface 22. A second anti-tarnish coating 30 is deposited onto the second, dendrite free, surface 24 of the substrate. 
     The first anti-tarnish coating 28 has a dark color distinguishing the first surface 22 from the second surface 24 which is coated with a transparent anti-tarnish coating. The dendritic surface is therefore readily recognized by either laborers or electronic equipment and may be rapidly placed adjacent to a dielectric substrate 32. 
     The first surface is then laminated to the dielectric substrate with the dendrites providing improved adhesion. As discussed above, the first anti-tarnish coating retards the formation of brass during lamination. 
     Following lamination, the second anti-tarnish coating 30 is removed by contact with a dilute acid such as 5% by weight sulfuric acid. A chemically resistant resist 34 as illustrated in FIG. 4 is then selectively deposited on the second surface 24. 
     The foil substrate 12 is selectively etched as known in the art to form a plurality of circuit traces 36 as illustrated in FIG. 5. The etchant removes the substrate selectively exposed by the chemical resist 34 as well as the dendrites and first anti-tarnish layer underlying the exposed substrate. Since the first anti-tarnish layer is a high zinc content, chromium-zinc layer which is essentially brass free, removal is complete in the etchants typically used to etch the substrate with minimal undercutting. 
     The portion 28&#39; of the first anti-tarnish coating which underlies the circuit traces 36 is not etched and remains as a barrier layer between the dielectric substrate 32 and the circuit traces. 
     The improvements achieved with anti-tarnish coatings applied by the method of the present invention will be more clearly understood by the examples which follow. 
     EXAMPLE A 
     A copper foil produced by electrodeposition was given an anti-tarnish coating according the method of the present invention. The foil had a smooth surface corresponding to the side of the foil which was in contact with the cathode during electrodeposition and a rough surface corresponding to the opposite side of the foil. The foil was coated with a chromium-zinc anti-tarnish coating by immersion in an electrolyte solution containing 100 grams per liter NaOH, 8.5 grams per liter ZnO, and 75 grams per liter Na 2  Cr 2  O 7 .2H 2  O. A current density of 5 mA/cm 2  was impressed on the foil. Dwell time within the anodes was 15 seconds. After coating, the foil was rinsed in distilled water for 15 seconds and dried with forced air. 
     The coated foil was tested for tarnish resistance. A simulated printed circuit board lamination thermal cycle was employed. The simulation comprised a 30 minute air bake at 190° C. Throughout the Examples, the expression &#34;simulated lamination&#34; or equivalent refers to a thermal cycle comprising a 30 minute air bake at 190° C. No discoloration was observed on the shiny side of the foil after the simulation. Extensive discoloration was noted on the rough side of the foil. 
     The anti-tarnish film was easily removed from both sides of the copper foil with 4% HCl. Total removal of the anti-tarnish film was verified by exposing the foil to (NH 4 ) 2  S fumes. The foil turned blue indicating interaction between the fumes and copper. 
     EXAMPLE B 
     A second strip of electrodeposited copper foil was given an anti-tarnish coating according to the method of the invention. The electrolyte contained 20 grams per liter NaOH, 1.7 grams per liter ZnO, and 15 grams per liter Na 2  Cr 2  O 7 .2H 2  O. After coating, the foil was rinsed in distilled water followed by a rinse in distilled water containing 100 parts per million of Ca(OH) 2 . The shiny side of the foil exhibited no discoloration following simulated lamination. The anti-tarnish coating was completely removed with immersion in a 4 percent HCl solution. 
     The roughened side of the electrodeposited foil was not evaluated. 
     EXAMPLE C 
     An electrodeposited copper foil strip was given an anti-tarnish coating according to the method of the invention. The electrolyte solution contained 20 grams per liter NaOH, 0.85 grams per liter ZnO, and 1.5 grams per liter Na 2  Cr 2  O 7 .2H 2  O. Following electrolytic deposition, the strip was rinsed in distilled water followed by a rinse in distilled water containing 100 ppm Ca(OH) 2  and 1 milliliter per liter silane. After drying the anti-tarnish coating on the shiny side of the strip was evaluated. No discoloration was detected during simulated lamination and the coating was rapidly removed with 4% HCl. The roughened side of the strip was not evaluated. 
     EXAMPLE D 
     A wrought copper foil having one side roughened with dendritic copper by the COPPERBOND® process was given an anti-tarnish coating according the method of the invention. The electrolyte solution contained 20 grams per liter NaOH, 1 gram per liter ZnO, and 1 gram per liter Na 2  Cr 2  O 7 .2H 2  O. The solution temperature was varied between room temperature and 65° C. Following application of the coating, the foil was rinsed in distilled water containing 100 ppm of Ca(OH) 2 , heated to a temperature of about 70° C. for 25 seconds and then dried by forced air. Various current densities were applied during deposition. 
     After drying, the coated strip was evaluated for discoloration and ease of removal of the coating as detailed above. At a total electrical charge of about 50 mC/cm 2  (mC stands for millicoulomb and represents mA×seconds (5 mA ×10 seconds=50 mA/cm 2 ), the shiny surface of the wrought foil met all requirements. At a total charge of 70 mC/cm 2  (7 mA×10 seconds), the roughened surface of the wrought foil also passed the evaluation tests. 
     EXAMPLE E 
     Wrought foil with one side roughened as in Example D was coated in solutions containing 20 grams per liter NaOH, 1 gram per liter ZnO, and either 3 grams or 10 grams per liter Na 2  Cr 2  O 2  O 7 .2H 2  O. Good tarnish resistance as determined by the simulated lamination cycle was achieved on the shiny surface. However, the roughened surface showed marginal tarnish resistance with the coating from the solution containing 3 grams per liter dichromate and no tarnish resistance when coated in the solution containing 10 grams per liter dichromate. As the chromium (VI) ion concentration was increased from 0.39 gm/l (Example D) to 1.18 gm/l (Example E) to 3.9 gm/l (Example E), the anti-tarnish resistance steadily decreased. As discussed above, at least one of the zinc ion or chromium (VI) ion concentration is maintained below 1.0 gm/l. 
     EXAMPLE F 
     Wrought foil having a shiny side and a roughened side as above was coated according to the method of the invention using the solution of Example D. The post plating rinse contained only distilled water. The caustic additive was eliminated. Following the simulated lamination cycle, the shiny surface of the foil had no discoloration, however, the roughened surface was tarnished. 
     EXAMPLE G 
     Wrought foil having a shiny side and a roughened side was coated according to the method of the invention using the solution of Example D. The amperage impressed on the anode 20 facing the shiny side of the foil was 36 amps while the anode facing the roughened side of the foil was 54 amps. The plating time was about 12 seconds. 
     The coating so produced was readily and rapidly removed in a 5 wt% H 2  SO 4  solution. This is an advantage over the commercially available Cr/Zn coating described above which is not removable in a 5 wt% H 2  SO 4  etchant. 
     The composition of the coating layer was determined by Electron Spectroscopy for Chemical Analysis (ESCA) and the shiny side composition was determined to be 5 atomic % Cr; 21% Zn; 56% O; 16% C and 1% Cu. A difference between the coating layer produced by the method of the invention and the commercially available Cr/Zn coating is the ratio of zinc to chromium. While the commercially available coating has a 2:1 ratio, the method of the invention produced a ratio in excess of 4:1 for the conditions of Example G. 
     The thickness of the coating layer was next determined by Auger Electron Spectroscopy. The technique employs an X-Ray source to sputter away the surface of the sample at a controlled rate, for example, 10 angstroms per minute. The composition of the vaporized material is analyzed. A 50% copper level was considered to indicate the substrate had been reached. The thickness of the coating layer of the invention was determined to be about 40 angstroms as compared to about 80 angstroms for the commercially available material. The satisfactory properties of the anti-tarnish coating of the invention at 40 angstroms indicates a coating thickness in the range of about 10 angstroms to about 100 angstroms would be sufficient. 
     Both the commercially available material and the foil coated according to Example G were subjected to the simulated lamination. Higher bake tests at 210° C. and 230° C. both for 30 minutes in air were also evaluated. As illustrated in Table 2, the coating layer produced by the process of the invention is clearly superior to the commercially available material. 
     
                       TABLE 2                                                     
______________________________________                                    
          Results                                                         
            Invention     Commercial                                      
Bake Test   Rough/Shiny Side                                              
                          Rough/Shiny Side                                
______________________________________                                    
190° pass/pass     fail/pass                                       
210° pass/pass     fail/pass                                       
230° pass/fail     fail/fail                                       
______________________________________                                    
 
    
     EXAMPLE H 
     To determine the effect of temperature on the zinc to chromium ratio as well as to determine a preferred zinc to chromium ratio, an electrolyte containing 20 grams per liter sodium hydroxide, 0.99 grams per liter zinc ions and a chromium (VI) ion concentration as indicated in Table 3 was utilized to coat wrought copper foil. The solution temperature was as indicated in Table 3. A current density of 8 mA/cm 2  was impressed across the electrolyte with the copper foil strip as the cathode. The current was applied for 12 seconds. After deposition of an anti-tarnish coating, a bake test in accordance with the simulated lamination of Example A was performed. 
     The zinc to chromium ratio was determined using Auger Electron Spectroscopy. To avoid surface contamination, approximately the top 30 angstroms of the coating was removed by argon ion etching prior to the analysis. As shown in Table 3, increasing the temperature of the electrolyte increases the zinc to chromium ratio. It can also be seen from Table 3 that while any zinc to chromium ratio in excess of about 4:1 is acceptable, a preferred zinc to chromium ratio is from about 5:1 to about 12:1. A most preferred zinc to chromium ratio is from about 6:1 to about 10:1. 
     
                       TABLE 3                                                     
______________________________________                                    
                                   Simulated                              
Cr (VI) Concentr.                                                         
             Electrolyte                                                  
                       Deposited   Lamination                             
(grams per liter)                                                         
             Temp. °F.                                             
                       Zn:Cr Ratio Results                                
______________________________________                                    
0.2          130       7.2         pass                                   
0.2          160       13.8        pass bake test                         
                                   dark grey                              
                                   appearance                             
2.0          110       4.7         fail                                   
2.0          130       7.9         pass                                   
0.1          130       3.2         fail                                   
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     From the examples above, it may be seen that an anti-tarnish coating may be applied to a copper or copper based alloy strip by electrolytic deposition. Smooth and shiny surfaces are easily coated. Electrolytic solutions containing a caustic component, zinc oxide and a hexavalent chromium salt within a specified range of compositions are acceptable. Rinsing may be in either distilled water or distilled water containing a caustic additive. 
     Effective solutions to electrolytically deposit an anti-tarnish coating on a roughened copper or copper base alloy surface are more limited in composition. The chromium (VI) concentration should be maintained below about 1.5 grams per liter. Preferably, the chromium (VI) concentration should not exceed about 1.0 grams per liter. Following deposition of the anti-tarnish coating, the coated strip is preferably rinsed in a solution of distilled water containing a small concentration of a caustic. 
     As discussed above, the addition of an organic additive such as lauryl sulfate to the electrolyte is believed to improve the properties of the anti-tarnish coating. At 30 ppm lauryl sulfate, the oxidation resistance of the coating was found to extend to about 10° C. higher than a coating deposited from the same electrolyte without the additive. Other properties such as peel strength and acid removability were not affected. The effective composition of the surfactant is believed to be from about 10 ppm to about 50 ppm. 
     While not fully understood, the co-electrodeposited anti-tarnish layer is believed to be either an alloy of chromium and zinc or a partial hydroxide compound of those elements or mixtures of such alloys and compounds. It is also believed that the coating includes a higher weight percentage of zinc as compared to chromium. 
     While the anti-tarnish is particularly suited for application to copper or copper based alloy foils for use in printed circuit board applications, properties of any copper or copper based alloy material may be improved by the coatings of the invention. For example, the tarnish-resistance of any copper strip may be improved by coating with the chromium zinc anti-tarnish coatings. Also, leadframe adhesion to an epoxy polymer is improved. 
     The patents and patent applications cited in this application are intended to be incorporated by reference. 
     It is apparent that there has been provided in accordance with this invention electrolytic solutions for depositing a chromium-zinc anti-tarnish coating on copper or a copper based alloy substrate as well as a means for the deposition of such a coating which fully satisfy the objects, means, and advantages set forth hereinbefore. While the invention has been described in combination with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, it is intended to embrace all such alternatives, modifications and variations as fall within the spirit and broad scope of the appended claims.