US3198659A - Thin nickel coatings - Google Patents

Thin nickel coatings Download PDF

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US3198659A
US3198659A US185830A US18583062A US3198659A US 3198659 A US3198659 A US 3198659A US 185830 A US185830 A US 185830A US 18583062 A US18583062 A US 18583062A US 3198659 A US3198659 A US 3198659A
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nickel
solution
plating
hydrazine
coatings
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Donald J Levy
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Lockheed Corp
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    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C18/00Chemical coating by decomposition of either liquid compounds or solutions of the coating forming compounds, without leaving reaction products of surface material in the coating; Contact plating
    • C23C18/16Chemical coating by decomposition of either liquid compounds or solutions of the coating forming compounds, without leaving reaction products of surface material in the coating; Contact plating by reduction or substitution, e.g. electroless plating
    • C23C18/31Coating with metals
    • C23C18/32Coating with nickel, cobalt or mixtures thereof with phosphorus or boron
    • C23C18/34Coating with nickel, cobalt or mixtures thereof with phosphorus or boron using reducing agents

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  • the present invention relates to nickel coatings which possess unique chemical and physical properties and to the processes and baths for producing said nickel coatings. More particularly, it relates to thin nickel coatings which possess certain preferred chemical and magnetic properties and to an autocatalytic chemical reduction process for producing thin nickel coatings which process incorporates solutions of special composition.
  • the coatings produced by the prior art contain phosphorus in sufiicient quantity to substantially diminish the purity level of the nickel coating and thereby prohibit or restrict the use of these coatings in applications where a high level of nickel purity is essential and especially in applications where the presence of phosphorus cannot be tolerated.
  • the general purpose of this invention is, therefore, to provide by an autocatalytic plating technique a nickel coating that is substantially free of impurities and exhibits, as a consequence, properties hitherto unobtainable in nickel in thin film condition. T o accomplish this result, the present invention contemplates unique plating bath compositions whereby substantially impurity-free coatings of nickel are realized.
  • a still further object of the invention is to provide nickel coatings which possess unusual magnetic properties.
  • Another object of the invention is the provision of thin nickel coatings of high saturation magnetization.
  • Yet another object of the invention is the provision of coatings of uniform thickness whereby homogeneous magnetic characteristics result.
  • a still further object is the provision of nickel coatings having a range of radiation absorption and emission characteristics which may be selectively varied.
  • An additional object is the provision of a nickel coating having, as one of its properties, high specularity.
  • Another object of the invention is to provide a nickel film having high adhesion characteristics whereby excellent film adherence to the substrate is effected.
  • a further object of the invention is the provision of thin nickel coatings obtainable by autocatalytic deposition.
  • a still further object of the invention is to provide new and improved chemical nickel plating solutions which are relatively stable and which do not decompose spontaneously during the plating reaction.
  • a still further object of the invention is to provide ice nickel plating solutions and processes which do not require elaborate electrical equipment for use in conjunction therewith.
  • reaction (1) above is catalyzed and metallic nickel is deposited on the surface of the article.
  • This reduction of nickel cations to metallic nickel occurs with out the use of an external power source since the plating bath itself contains a reductant, hydrazine, which provides the necessary electrons to reduce the nickel cations.
  • the newly plated nickel surface which is itself catalytic, serves as a catalyst for further nickel plating.
  • the process is properly referred to as autocatalytic due to its self-sustaining nature whereby reaction contin ues and nickel metal is deposited on the article until it is withdrawn from solution. Film thickness, consequently,
  • the nickel ion referenced in Table l is the free aquo ion, presumably Ni(H O) and it may be derived from the ionization of any nickel salt of adequate solubility, e.g., nickel chloride, nickel nitrate, nickel sulfate, nickel acetate, nickel sulfamate. Since the Ni++ concentration would be rapidly depleted during plating under practical commercial conditions, some means of conveniently adding Ni++ at the same rate that they are removed by the plating reaction is desired. One method is to add at an appropriate rate to the solution an excess of a nickel salt whose solubility matches the desired Ni++ concentration. A second. and preferred method is to add a complexing agent to the solution and complex all Ni++ greater than the quantity desired.
  • any nickel salt of adequate solubility e.g., nickel chloride, nickel nitrate, nickel sulfate, nickel acetate, nickel sulfamate. Since the Ni++ concentration would be rapidly depleted during plating under practical commercial conditions, some means
  • metal complexers dissociate in aqueous solution to form and maintain a relatively constant concentration of free metal ion, the concentration of free metal ion depending on the amount and nature of the complexer used.
  • the complexing agents which are suitable for this process are vast in number and character.
  • the donor atom may be oxygen,
  • a nitrogen, or other specie in a ligand (complexer) of monoor poly-dentate structure ea nitrogen, or other specie in a ligand (complexer) of monoor poly-dentate structure.
  • Carboxylates, hydroxycarboxylates, and amines are particularly satisfactory. The various types and the method in which they are employed will become evident in subsequent examples and descriptions of the process.
  • the amount of soluble nickel in the complexed form which is present in the solution is arbitrary and may vary from nil to large amounts limited only by the solubility of the most soluble nickel salt. It is clear, therefore, that the preferred ranges for the total quantities of nickel salt in solution may vary considerably as long as a suitable complexing agent is available to tie up the dissociated nickel salt as a complex ion so that only 10- to l"- g. ions/liter of free nickel cations are present in the bath.
  • the concentration of hydrazine used may be varied over wide limits.
  • the plating rate is found to increase with hydrazine concentration up to a saturation value (about 1 molar with one set of conditions) beyond which the rate remains constant irrespective of hydrazine concentration as high as 5 molar.
  • the hydrazine functions as a chemical reductant in the process such that other inorganic and organic functionally substituted hydrazine compounds and their derivatives may be used in place of the parent compound so long as they have adequate solubility.
  • hydrazine sulfate, hydrazine hydrochloride, methyl hydrazine and hydroxyethyl hydrazine are all suitable reductants for the purpose of this invention.
  • the plating rate increases with temperature so that operating temperatures of 9095 C. are generally decomposition of the solution occurs.
  • the following procedure is suggested for making up plating solutions in accordance with the instant invention: First dissolve the nickel-containing salt in a quantity of water to form a first solution. Next dissolve the complexing agent, such as a tartrate, in a quantity of water to form a second solution. Add the first and second solutions together and to the resulting mixture add the hydrazine solution. Finally, add the hydroxide solution and quantity of water required to bring the total up to the necessary composition. Heat the bath to the desired temperature and it is ready for use.
  • EXAMPLE I A plating solution was prepared and mixed in the proper order to comprise 0.05 mole per liter (m.p.l.) of nickel chloride, 0.1S mp1. hydrazine, and 0.01 m.p.l. ammonium carbonate. This solution was heated to a temperature of 90 C. and maintained at a pH of 6.8.
  • a glass microscope slide was used as a substrate and was ensitized with palladium by the common and well known technique of cleaning by immersion in hot chromic acid solution, rinsing with water, immersing in stannous chloride solution, again rinsing with water, immersing in palladium chloride solution, and finally water rinsing so as to coat the non-conductive glass with an invisible film of palladium and thus impart to the surface the characteristics of a catalytic metal.
  • the slide thusly prepared was then immersed into the plating solution for 5 minutes, water rinsed, and dried. The slide was found to be coated with a bright film of nickel about 700 A. thick.
  • EXAMPLE IV A glass microscope slide was cleaned and sensitized as described in Example I.
  • a plating solution was prepared which contained 0.02 111.111. NiCl 0.005 sodium malonate, 0.1 m.p.l hydrazine, and which was adjusted to a pH of 7.5 and heated to 95 C.
  • the sensitized slide was im- 1 ersed into the plating solution for three minutes after which the plated sample was rinsed and dried.
  • Upon examination of the specimen in a 8-H hysteresis loop tester, it was found that the coercivity, H was only 16 oersteds, an unusually low and desirable value and the loop showed good squareness, B /B 0.92.
  • the plating reaction will initiate spontaneously on all clean surfaces which will function catalytically for hydrogenation-dehydrogenation reactions.
  • catalytic materials include, among others, platinum, palladium, nickel, gold and iron.
  • articles composed of substances which are not catalytic they may be first coated with a thin layer of some catalytic material by such techniques as electroplating, immersion plating, vacuum evaporation, painting with conductive paints, or other appropriate methods.
  • a well known method of sensitizing nonconductors with a film of palladium was described in Example I.
  • the process consists of immersing the article to be coated into the plating solution.
  • it is usually desirable to maintain the plating solution at a rather constant composition or within a small composition range. Consequently, one may make additions of the constituents which become depleted because of the plating reaction, evaporation, and drag-out losses. These additions may be made continuously or batch-wise at intervals.
  • the present invention can be readily practiced as a continuous process by well-known techniques whereby pumps, filters and storage tanks are employed to recirculate and regenerate the plating solution.
  • the thickness of the coating is a direct function of solutitan-article cont-act time, other factors remaining constant. Films in the order of A. have been prepared and thinner films are possible. Conversely very thick coatings can be prepared, if required for a specific application, since adhesion is excellent. Furthermore, the process causes the deposition of films of uniform thickness irrespective of the geometrical complexity of the article surface.
  • the complexer may be selected to function dually as one half of a pH buffer pair, or alternately, a pH buffer may be added.
  • trace quantities of catalyst poisons may be added so as to prevent tiny suspended particulates from precipitating general decomposition of the plating solution. It was found that substances, e.g., malonates, with a great alfinity for protons, accelerated the plating rate. Such substances may be added to function separately or dually (as a com plexer also). Additional refinements, known in the art of metal deposition from aqueous solutions, may be employed within the scope of the process of this invention.
  • NICKEL FILM PROPERTIES In order to determine the compositional impurities in the nickel films, special techniques for analysis had to be employed. Unsupported nickel films of approximately 1,000 angstroms in thickness were examined by elastic scattering of particles emitted from a Van de Graalf accelerator. The principal impurities to be found in the nickel film are hydrogen, nitrogen, and oxygen. The hydrogen content in the nickel film was found to he approxi 'mately .1 to 0.2 percent by weight of hydrogen as determined by proton-proton scattering with the Van de Graatf accelerator. Some difficulties were encountered in a-t believed to determine the oxygen and nitrogen content using 2.3 mev.
  • M was determined by the Guoy method using a permanent magnet with a field strength of 500 gauss per centimeter. It was found that the M of the samples varied from between about 80% and 90% of the theoretical maximum for bulk nickel (484 gauss per centimeter irrespective of the complexing donor atom species, pH in the range of 7 to 10, film color, or other parameters. However, certain films were found to exhibit M values essentially equal to that of bulk nickel, and in some cases exhibited apparent M s at least equal to 484 gauss per centimeter the nickel films which exhibited the highest M values were those which were plated onto copper sheet.
  • the nickel films of the present invention possess desirable square B-H loop characteristics and a majority of the samples exhibited a fl of at least 0.8 and moreover, possess desirable low coercivity in the range of from -30 oersteds. It is of interest to note that the obtention of a square hysteresis loop by the instant process is an unusual characteristic for nickel. However, just exactly why this effect has been achieved in the practice of the invention is not fully understood at the present time.
  • glass substrates are sensitized with a palladium strike plate in predetermined areas using an appropriate masking device.
  • Immersion of the sensitized ceramic substrate into the preferred solutions of the instant invention will result in the formation of nickel films at these preselected areas which films will represent a multitude of individual memory disks of abovementioned preferred magnetic characteristics substantially as previously described.
  • the same result may be likewise achieved through utilization of chemical resist-coating technique whereby selected areas are coated with a material that resists subsequent etching steps.
  • Other applications of the film will obviously suggest themselves by virtue of the desirable magnetic characteristics which the film possesses as hereinabove pointed out.
  • the invention provides a commercially practicable chemical nickel plating solution and a resultant nickel film which has unique chemical and physical properties.
  • relatively thick coatings of nickel may be autocatalytically plated without requiring the use of elaborate and expensive electrical equipment, and yet, any desired thickness of nickel plating can be formed up to a predetermined maximum thickness.
  • the nickel plating may be readily formed on irregularly shaped objects and surfaces, with the assurance that such irregularly shaped surfaces will receive a uniform coating of nickel.
  • the invention provides a plating solution and process capable of carrying out the above objects which solution is relatively stable and the process is relatively simple to conduct.
  • An aut-ocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface comprising the steps of providing an aqueous solution comprised of free nickel ions in the amount of from 10" to 10- gram-ions per liter, and a recluctant selected from the group consisting of hydrazine and hydrazine derivatives, maintaining said solution at a tempera- .ture of from 70 to 100 C. and at a pH of from 6.5 to
  • a bath for the autocatalytic plating of nickel on catalytic metal surfaces comprising an aqueous solution of free nickel ions in the amount of from l0 to l0 gram-ions per liter and hydrazine in the amount of from 0.05 to 3 gram moles per liter, said solution having a pH greater than 6.5.
  • An autocatalytic chemical reduction process for plating nickel on objects having a catalytic metal surface comprising the steps of providing an aqueous solution containing from l0 to l0- gram-ions per liter of free nickel ions, 0.05 to 3 moles per liter of hydrazine, maintaining said solution at a temperature in the range of from C. to C. and a pH greater than 6.5, immersing the object to be plated in the solution, and continuously plating a nickel film on said object by the autocatalytic reaction of said solution at the catalytic metal surface until the desired film thickness is obtained.
  • An autocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface comprising the steps of providing an aqueous solution containing from about 0.02 to about 0.2 gram moles per liter of a nickel salt, at least one nickel complcxer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 gram moles per gram mole of nickel salt, and about 0.05 to 3 gram moles per liter of hydrazine; maintaining said solution at a temperature of from 70 C. to 100 C. and at a pH of from 6.5 to 11; immersing said obiect in said solution to plate nickel on said object by the autocatalytic reaction of said solution at the catalytic metal surface, and removing said plated obiect from said solution.
  • a bath for the autocatalytic plating of nickel on catalytic metal surfaces comprising an aqueous solution of about 0.02 to about 0.2 gram moles per liter of a nickel salt, at least one nickel complexer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 gram moles per gram mole of nickel salt, and about 0.05 to 3 gram moles of hydrazine per liter of solution, said solution having a pH of from 6.5 to 11.
  • An autocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface comprising the steps of proan aqueous solution of a nickel salt, a nickel complexing agent in the amount of l to 10 moles per mole of nickel salt, and a reductant selected from the group consisting of hydrazine and hydrazine derivatives, maintaining said solution at a temperature of from about 70 C. to about 100 C. and at a pH greater than 6.5, contacting said object with said solution, plating nickel on said object by the autocatalytic reaction of said solution at the catalytic metal surface, and removing said plated object from said solution.
  • a bath for the autocatalytic plating of nickel on catalytic metalsurfaces comprising an aqueous solution of a nickel salt selected from the group consisting of nickel chloride, nickel sulfate, nickel acetate, nickel nitrate, and nickel sulfarnate, a complexer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 moles per mole of nickel salt,
  • a reductant selected from the group consisting of hydrazine and hydrazine derivatives, said solution having a pH greater than 6.5.

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Description

United States Patent 3,193,659 THEN NECKEL (IQATINGS Donald LLevy, Mountain View, Calif assignor to Lockheed Aircraft (Iorporation, Burbank, Calif. No Drawing. Filed Apr. 9, 1962, Ser. No. 185,830 7 Claims. (61. Zll7-Il3ll) The present invention relates to nickel coatings which possess unique chemical and physical properties and to the processes and baths for producing said nickel coatings. More particularly, it relates to thin nickel coatings which possess certain preferred chemical and magnetic properties and to an autocatalytic chemical reduction process for producing thin nickel coatings which process incorporates solutions of special composition.
Heretofore, it has been the practice to produce nickel coatings by autocatalytic deposition by means of immersing catalytic surfaces in plating baths containing nickel cations and hypophosphite ions. Although the coatings produced have been highly satisfactory for their intended.
use, they have invariably contained impurities in such quantities that requisite physical and chemical properties for certain applications are seriously affected. In particular, the coatings produced by the prior art contain phosphorus in sufiicient quantity to substantially diminish the purity level of the nickel coating and thereby prohibit or restrict the use of these coatings in applications where a high level of nickel purity is essential and especially in applications where the presence of phosphorus cannot be tolerated.
The general purpose of this invention is, therefore, to provide by an autocatalytic plating technique a nickel coating that is substantially free of impurities and exhibits, as a consequence, properties hitherto unobtainable in nickel in thin film condition. T o accomplish this result, the present invention contemplates unique plating bath compositions whereby substantially impurity-free coatings of nickel are realized.
It is, therefore, one object of the present invention to provide thin nickel coatings of relatively high purity.
it is another object of the invention to provide a nickel coating which is substantially devoid of the impurity phosphorus.
A still further object of the invention is to provide nickel coatings which possess unusual magnetic properties.
Another object of the invention is the provision of thin nickel coatings of high saturation magnetization.
It is another object of the invention to provide thin nickel coatings which exhibit a hysteresis loop with a high squareness ratio, B /B Still another object is to provide a nickel coating of low coercivity.
Yet another object of the invention is the provision of coatings of uniform thickness whereby homogeneous magnetic characteristics result.
A still further object is the provision of nickel coatings having a range of radiation absorption and emission characteristics which may be selectively varied.
An additional object is the provision of a nickel coating having, as one of its properties, high specularity.
Another obiect of the invention is to provide a nickel film having high adhesion characteristics whereby excellent film adherence to the substrate is effected.
A further object of the invention is the provision of thin nickel coatings obtainable by autocatalytic deposition.
A still further object of the invention is to provide new and improved chemical nickel plating solutions which are relatively stable and which do not decompose spontaneously during the plating reaction.
A still further object of the invention is to provide ice nickel plating solutions and processes which do not require elaborate electrical equipment for use in conjunction therewith.
It is another object of the invention to provide nickel coatings which have decorative appeal, improved corrosion resistance, and properties making them exceptionally useful as chemical reaction catalysts.
In the practice of the present invention, it has been found that a reaction takes place between nickel ions and hydrazine such that metallic nickel is deposited. It is believed that the overall chemical reaction can be described by the following equation:
When a vessel is provided with nickel ions and hydrazine in aqueous solution in the proportions and under the conditions specified hereinafter and, subsequently, an article of catalytic material such as copper is immersed into the solution, reaction (1) above is catalyzed and metallic nickel is deposited on the surface of the article. This reduction of nickel cations to metallic nickel occurs with out the use of an external power source since the plating bath itself contains a reductant, hydrazine, which provides the necessary electrons to reduce the nickel cations. The newly plated nickel surface, which is itself catalytic, serves as a catalyst for further nickel plating. There fore, the process is properly referred to as autocatalytic due to its self-sustaining nature whereby reaction contin ues and nickel metal is deposited on the article until it is withdrawn from solution. Film thickness, consequently,
is a linear function of immersion time provided the nickel ions and hydrazine are maintained at a substantially constant concentration in the solution.
BATH COMPOSITION AND OPERATING COrlDITlONS Table I Ni++, g. ions/liter 10- to 10- Hydrazine, moles/liter 0.05-3 (preferred). Temperature, C. 70-100 (preferred -95). pH 6.5 min. (preferred 7-11).
The nickel ion referenced in Table l is the free aquo ion, presumably Ni(H O) and it may be derived from the ionization of any nickel salt of adequate solubility, e.g., nickel chloride, nickel nitrate, nickel sulfate, nickel acetate, nickel sulfamate. Since the Ni++ concentration would be rapidly depleted during plating under practical commercial conditions, some means of conveniently adding Ni++ at the same rate that they are removed by the plating reaction is desired. One method is to add at an appropriate rate to the solution an excess of a nickel salt whose solubility matches the desired Ni++ concentration. A second. and preferred method is to add a complexing agent to the solution and complex all Ni++ greater than the quantity desired. It is well known in coordination chemistry that metal complexers dissociate in aqueous solution to form and maintain a relatively constant concentration of free metal ion, the concentration of free metal ion depending on the amount and nature of the complexer used. The complexing agents which are suitable for this process are vast in number and character. The donor atom may be oxygen,
ea nitrogen, or other specie in a ligand (complexer) of monoor poly-dentate structure. Carboxylates, hydroxycarboxylates, and amines are particularly satisfactory. The various types and the method in which they are employed will become evident in subsequent examples and descriptions of the process. The amount of soluble nickel in the complexed form which is present in the solution is arbitrary and may vary from nil to large amounts limited only by the solubility of the most soluble nickel salt. It is clear, therefore, that the preferred ranges for the total quantities of nickel salt in solution may vary considerably as long as a suitable complexing agent is available to tie up the dissociated nickel salt as a complex ion so that only 10- to l"- g. ions/liter of free nickel cations are present in the bath.
Consequently, the concentration of hydrazine used may be varied over wide limits. The plating rate is found to increase with hydrazine concentration up to a saturation value (about 1 molar with one set of conditions) beyond which the rate remains constant irrespective of hydrazine concentration as high as 5 molar. The hydrazine functions as a chemical reductant in the process such that other inorganic and organic functionally substituted hydrazine compounds and their derivatives may be used in place of the parent compound so long as they have adequate solubility. For example, hydrazine sulfate, hydrazine hydrochloride, methyl hydrazine and hydroxyethyl hydrazine are all suitable reductants for the purpose of this invention.
The plating rate increases with temperature so that operating temperatures of 9095 C. are generally decomposition of the solution occurs. For this reason, the following procedure is suggested for making up plating solutions in accordance with the instant invention: First dissolve the nickel-containing salt in a quantity of water to form a first solution. Next dissolve the complexing agent, such as a tartrate, in a quantity of water to form a second solution. Add the first and second solutions together and to the resulting mixture add the hydrazine solution. Finally, add the hydroxide solution and quantity of water required to bring the total up to the necessary composition. Heat the bath to the desired temperature and it is ready for use.
The method of this invention and the desirable properties of the nickel coating will become apparent in the detailed examples which follow.
EXAMPLE I A plating solution was prepared and mixed in the proper order to comprise 0.05 mole per liter (m.p.l.) of nickel chloride, 0.1S mp1. hydrazine, and 0.01 m.p.l. ammonium carbonate. This solution was heated to a temperature of 90 C. and maintained at a pH of 6.8. A glass microscope slide was used as a substrate and was ensitized with palladium by the common and well known technique of cleaning by immersion in hot chromic acid solution, rinsing with water, immersing in stannous chloride solution, again rinsing with water, immersing in palladium chloride solution, and finally water rinsing so as to coat the non-conductive glass with an invisible film of palladium and thus impart to the surface the characteristics of a catalytic metal. The slide thusly prepared was then immersed into the plating solution for 5 minutes, water rinsed, and dried. The slide was found to be coated with a bright film of nickel about 700 A. thick.
In similar fashion, nickel films were deposited on other glass slides using the plating solutions listed in Table I1 below.
T able II Bath Composition, moles/liter Operating Conditions Plating Plating Rat e, Jug. Appearance Ni/cm NiCl; Complexcr Hydrasine pH C.
0.02.- 0.1 n1aJ1dcllate 1.0 10 95 0. 90 Dark. 0.02 .06 glycine-c 1.0 10 95 0.87 Do. 0.02 .08 ethylene diamme 1.0 10 95 0.28 Do. 0.02 .10 maleate 1.0 10 95 0. 09 Do. 0.02 .03 triethylcnetetraamine 1.0 10 95 0. 06 Bright. 0.02 .0 1.0 10 95 0. 02 D0. 0.03 .0 1.0 10 95 0.30 Lt. brown. 01 .2 1. 0 10 95 0.28 Bright. 0.02 0.02 tartrato- 0.65 10 95 0. 28 D0. 0. 0.02 tartrato 2.0 10 05 0.31 Brown. 0. 0.01 ammonium e 0. 6. 8 90 0. 07 Bright. 0. 0.02 ammonium carbonate 0.05 8. 3 90 0.23 Do.
.NaOH, KOl-l, NH OI-I and other metal hydroxides of adequate solubility.
In practice, it is desirable to have a stable solution, that is, one that does not generally decompose by a homogeneous reaction of Equation 1 and deposit finely divided nickel particles throughout the solution. This homogeneous reaction accompanies the plating reaction only when one attempts to obtain too hi h a plating rate. The situation is easily corrected by reducing the Ni++ concentration, pH, or temperature individually or in combination.
The manner in which these new and improved nickel plating solutions are prepared can be quite important in that ingredients placed in the solution in an improper order may very well result in not all of the ingredients becoming dissolved; or else spontaneous homogeneous EXAMPLE II Coupons of copper sheet, .040 x 2" x 1", were cleaned by immersion in a dilute solution of nitric acid, water rinsed, and then immersed into the plating solutions as listed in Table III for periods of time suflicient to produce the thicknesses indicated. It was found that the saturation magnetization M of these films was unusually high compared to M for bulk nickel which is 484 gauss/cmfi. Because of a i3% instrumental error involved in testing these small samples, several of the average readings ran above the theoretical maximum. For example, in the third sample a value of 500 gauss/cm. was recorded, a figure which probably included approximately 16 gauss/ cm. as an experimental error in the measuring technique. Such a reading indicates that values equal to or extremely close to the theoretical maximum M of nickel were in fact achieved by the instant process. By way of contrast when nickel films were prepared by the prior art teachings utilizing a nickel-anion hypophosphite-cation type solution, 6 samples exhibited no detectable M while the other 4 showed values less than 100 gauss/cm.
(9 tion over or spraying solution on the catalytic surface of the article. Also, if desired, simultaneous dual spray application may be performed wherein nickel and hydrazine solutions are maintained separate with the other required EXAMPLE III A coupon of mild iron, .040" x 2 x 1", was cleaned by immersion in a dilute solution of hydrochloric acid, water rinsed, and then immersed into a plating solution composed of 0.02 m.p.l. NiCl 1.0 m.-p.l. hydrazine, and 0.04 m.p.l sodium malonate which was maintained at a temperature of 71 C. and a pH of 9.0. nickel deposited spontaneously on the iron coupon at the rate of 44-0 A./min. and that a bright, continuous, and firmly adherent coating was formed.
EXAMPLE IV A glass microscope slide was cleaned and sensitized as described in Example I. A plating solution was prepared which contained 0.02 111.111. NiCl 0.005 sodium malonate, 0.1 m.p.l hydrazine, and which was adjusted to a pH of 7.5 and heated to 95 C. The sensitized slide was im- 1 ersed into the plating solution for three minutes after which the plated sample was rinsed and dried. Upon examination of the specimen in a 8-H hysteresis loop tester, it was found that the coercivity, H was only 16 oersteds, an unusually low and desirable value and the loop showed good squareness, B /B =0.92.
PROCESS The plating reaction will initiate spontaneously on all clean surfaces which will function catalytically for hydrogenation-dehydrogenation reactions. It is well known that such catalytic materials include, among others, platinum, palladium, nickel, gold and iron. In the event that it is desired to coat articles composed of substances which are not catalytic, they may be first coated with a thin layer of some catalytic material by such techniques as electroplating, immersion plating, vacuum evaporation, painting with conductive paints, or other appropriate methods. A well known method of sensitizing nonconductors with a film of palladium Was described in Example I.
The process, as described, consists of immersing the article to be coated into the plating solution. In commerical practice, it is usually desirable to maintain the plating solution at a rather constant composition or within a small composition range. Consequently, one may make additions of the constituents which become depleted because of the plating reaction, evaporation, and drag-out losses. These additions may be made continuously or batch-wise at intervals. The present invention can be readily practiced as a continuous process by well-known techniques whereby pumps, filters and storage tanks are employed to recirculate and regenerate the plating solution.
Whereas the invention has been described by the technique of immersion of an article into a plating solution of specified composition, pH, and temperature, the invention shall not be limited to this type of article-solution contact. Contact may be achieved by flowing the solut was found that,
constituents added to one of these solutions, as appropriate.
The thickness of the coating is a direct function of solutitan-article cont-act time, other factors remaining constant. Films in the order of A. have been prepared and thinner films are possible. Conversely very thick coatings can be prepared, if required for a specific application, since adhesion is excellent. Furthermore, the process causes the deposition of films of uniform thickness irrespective of the geometrical complexity of the article surface.
In accordance with the present invention, other additives may be added to the plating solution for special purposes without detrimentally aifecting the plating action or the purposes of this invention. Since pH control is desirable to stabilize the plating rate, the complexer may be selected to function dually as one half of a pH buffer pair, or alternately, a pH buffer may be added. Likewise, trace quantities of catalyst poisons may be added so as to prevent tiny suspended particulates from precipitating general decomposition of the plating solution. It was found that substances, e.g., malonates, with a great alfinity for protons, accelerated the plating rate. Such substances may be added to function separately or dually (as a com plexer also). Additional refinements, known in the art of metal deposition from aqueous solutions, may be employed within the scope of the process of this invention.
NICKEL FILM PROPERTIES In order to determine the compositional impurities in the nickel films, special techniques for analysis had to be employed. Unsupported nickel films of approximately 1,000 angstroms in thickness were examined by elastic scattering of particles emitted from a Van de Graalf accelerator. The principal impurities to be found in the nickel film are hydrogen, nitrogen, and oxygen. The hydrogen content in the nickel film was found to he approxi 'mately .1 to 0.2 percent by weight of hydrogen as determined by proton-proton scattering with the Van de Graatf accelerator. Some difficulties were encountered in a-t tempting to determine the oxygen and nitrogen content using 2.3 mev. alpha particles, but in any event it was clearly shown that the nitrogen con-tent is definitely less than 2.5 percent and the oxygen content is likewise less than 2.5 percent. Because of the small quantities of nickel available'for analysis, accurate determinations to find out just how low the nitrogen and oxygen content are were not possible. Because of the lack of phosphorus in the plating environment, substantially no phosphorus is to e found in the film.
In order to determine the crystal structure of the nickel film, both electron and X-ray diffraction measurements were employed and it was determined that the structure is predominantly crystalline and possesses the normal face centered cubic lattice of bulk nickel. No preferred orientation of the crystal structure was evident through these analyses.
Saturation magnetization, M was determined by the Guoy method using a permanent magnet witha field strength of 500 gauss per centimeter. it was found that the M of the samples varied from between about 80% and 90% of the theoretical maximum for bulk nickel (484 gauss per centimeter irrespective of the complexing donor atom species, pH in the range of 7 to 10, film color, or other parameters. However, certain films were found to exhibit M values essentially equal to that of bulk nickel, and in some cases exhibited apparent M s at least equal to 484 gauss per centimeter the nickel films which exhibited the highest M values were those which were plated onto copper sheet. As seen in Example IV' the nickel films of the present invention possess desirable square B-H loop characteristics and a majority of the samples exhibited a fl of at least 0.8 and moreover, possess desirable low coercivity in the range of from -30 oersteds. It is of interest to note that the obtention of a square hysteresis loop by the instant process is an unusual characteristic for nickel. However, just exactly why this effect has been achieved in the practice of the invention is not fully understood at the present time.
in order to eifcctively use the desirable magnetic characteristics of the nickel film, glass substrates are sensitized with a palladium strike plate in predetermined areas using an appropriate masking device. Immersion of the sensitized ceramic substrate into the preferred solutions of the instant invention will result in the formation of nickel films at these preselected areas which films will represent a multitude of individual memory disks of abovementioned preferred magnetic characteristics substantially as previously described. The same result may be likewise achieved through utilization of chemical resist-coating technique whereby selected areas are coated with a material that resists subsequent etching steps. Other applications of the film will obviously suggest themselves by virtue of the desirable magnetic characteristics which the film possesses as hereinabove pointed out.
From the foregoing description it can be appreciated that the invention provides a commercially practicable chemical nickel plating solution and a resultant nickel film which has unique chemical and physical properties. By means of the invention, relatively thick coatings of nickel may be autocatalytically plated without requiring the use of elaborate and expensive electrical equipment, and yet, any desired thickness of nickel plating can be formed up to a predetermined maximum thickness. Furthermore, the nickel plating may be readily formed on irregularly shaped objects and surfaces, with the assurance that such irregularly shaped surfaces will receive a uniform coating of nickel. Also the invention provides a plating solution and process capable of carrying out the above objects which solution is relatively stable and the process is relatively simple to conduct.
Obviously other modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that changes may be made in the particular embodiments of the invention described which are within the full intended scope of the invention as defined by the appended class.
I claim as my invention:
1. An aut-ocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface comprising the steps of providing an aqueous solution comprised of free nickel ions in the amount of from 10" to 10- gram-ions per liter, and a recluctant selected from the group consisting of hydrazine and hydrazine derivatives, maintaining said solution at a tempera- .ture of from 70 to 100 C. and at a pH of from 6.5 to
11, immersing into said solution an object with a catalytic surface which will catalyze hydrogenation-dehydrogenation reactions maintaining said object in the solution for a predetermined time until a nickel layer of a preselected depth has been deposited and finally withdrawing the obice: from the solution.
2. A bath for the autocatalytic plating of nickel on catalytic metal surfaces comprising an aqueous solution of free nickel ions in the amount of from l0 to l0 gram-ions per liter and hydrazine in the amount of from 0.05 to 3 gram moles per liter, said solution having a pH greater than 6.5.
3. An autocatalytic chemical reduction process for plating nickel on obiects having a catalytic metal surface, said process comprising the steps of providing an aqueous solution containing from l0 to l0- gram-ions per liter of free nickel ions, 0.05 to 3 moles per liter of hydrazine, maintaining said solution at a temperature in the range of from C. to C. and a pH greater than 6.5, immersing the object to be plated in the solution, and continuously plating a nickel film on said object by the autocatalytic reaction of said solution at the catalytic metal surface until the desired film thickness is obtained.
s. An autocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface, said process comprising the steps of providing an aqueous solution containing from about 0.02 to about 0.2 gram moles per liter of a nickel salt, at least one nickel complcxer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 gram moles per gram mole of nickel salt, and about 0.05 to 3 gram moles per liter of hydrazine; maintaining said solution at a temperature of from 70 C. to 100 C. and at a pH of from 6.5 to 11; immersing said obiect in said solution to plate nickel on said object by the autocatalytic reaction of said solution at the catalytic metal surface, and removing said plated obiect from said solution.
5. A bath for the autocatalytic plating of nickel on catalytic metal surfaces comprising an aqueous solution of about 0.02 to about 0.2 gram moles per liter of a nickel salt, at least one nickel complexer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 gram moles per gram mole of nickel salt, and about 0.05 to 3 gram moles of hydrazine per liter of solution, said solution having a pH of from 6.5 to 11.
:5. An autocatalytic chemical reduction process for continuously plating nickel on objects having a catalytic metal surface, said process comprising the steps of proan aqueous solution of a nickel salt, a nickel complexing agent in the amount of l to 10 moles per mole of nickel salt, and a reductant selected from the group consisting of hydrazine and hydrazine derivatives, maintaining said solution at a temperature of from about 70 C. to about 100 C. and at a pH greater than 6.5, contacting said object with said solution, plating nickel on said object by the autocatalytic reaction of said solution at the catalytic metal surface, and removing said plated object from said solution.
'7. A bath for the autocatalytic plating of nickel on catalytic metalsurfaces comprising an aqueous solution of a nickel salt selected from the group consisting of nickel chloride, nickel sulfate, nickel acetate, nickel nitrate, and nickel sulfarnate, a complexer selected from the group consisting of a ligand having at least one oxygen donor atom, a ligand having at least one nitrogen donor atom, and a ligand having at least one oxygen donor atom and at least one nitrogen donor atom, said complexer being present in the ratio of about 1 to 10 moles per mole of nickel salt,
9 a reductant selected from the group consisting of hydrazine and hydrazine derivatives, said solution having a pH greater than 6.5.
References Cited by the Examiner UNITED STATES PATENTS 1G 3,032,436 5/62 Gostin 117-130 3,119,709 1/ 64 Atkinson 117-47 FOREIGN PATENTS 5 717,547 2/52 Germany.
OTHER REFERENCES Wein: The Glass Industries, September 1959, pages 476478, 500 and 502.
10 RICHARD D. NEVIUS, Primary Examiner.

Claims (1)

1. AN AUTOCATALYTIC CHEMICAL REDUCTION PROCESS FOR CONTINUOUSLY PLATING NICKEL ON OBJECTS HAVING A CATALYTIC METAL SURFACE COMPRISING THE STEPS OF PROVIDING AN AQUEOUS SOLUTION COMRPISED OF FREE NICKEL IONS IN THE AMOUNT OF FROM 10**-10 TO 10**-2 GRAM-IONS PER LITER, AND A REDUCTANT SELECTED FROM THE GROUP CONSISTING OF HYDRAZINE AND HYDRAZINE DERIVATIVES, MAINTIANING SAID SOLUTION AT A TEMPERATURE OF FROM 70* TO 100*C. AND AT A PH OF FROM 6.5 TO 11, IMERSING INTO SID SOLUTION AN OBJECT WITH A CATALYTIC SURFACE WHICH WILL CATALYZE HYDROGENATION-DEHYDROGENATION REACTIONS MAINTAINING SAID OBJECT ILN THE SOLUTION FOR A PREDETERMINED TIME UNTIL A NICKEL LAYER OF A PRESELECTED DEPTH HAS BEEN DEPOSITED AND FINALLY WITHDRAWING THE OBJECT FROM THE SOLUTION.
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US3416955A (en) * 1965-01-13 1968-12-17 Clevite Corp Electroless cobalt plating bath
US3470074A (en) * 1964-08-18 1969-09-30 Siemag Siegener Masch Bau Depositing zinc coatings
US3500927A (en) * 1968-02-16 1970-03-17 Shell Oil Co Electroless metalization of unconsolidated earth formations
US3915716A (en) * 1969-04-17 1975-10-28 Schering Ag Chemical nickel plating bath
US4590095A (en) * 1985-06-03 1986-05-20 General Electric Company Nickel coating diffusion bonded to metallized ceramic body and coating method
US4780342A (en) * 1987-07-20 1988-10-25 General Electric Company Electroless nickel plating composition and method for its preparation and use
EP0525282A2 (en) * 1991-06-24 1993-02-03 Shipley Company Inc. Controlled electroless plating
US5622877A (en) * 1993-03-02 1997-04-22 Ramot University Authority For Applied Research & Industrial Development Ltd. Method for making high-voltage high-speed gallium arsenide power Schottky diode
WO2017134282A1 (en) 2016-02-05 2017-08-10 Technische Universität München Joining of components by means of energetically activated reactive particles

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DE717547C (en) * 1938-05-03 1942-02-17 Dr Phil Willy Pragst Process for producing a firmly adhering, compact nickel mirror on glass or other non-conductors
US2430581A (en) * 1944-11-29 1947-11-11 Rca Corp Metallizing nonmetallic bodies
US2547838A (en) * 1947-11-26 1951-04-03 Russell Edward Wriothes Curzon Record bearing medium and methods of preparation
US2801935A (en) * 1953-09-30 1957-08-06 Merck & Co Inc The use of hydrazine tartrate salts in the chemical deposition of metals
US2808345A (en) * 1953-04-23 1957-10-01 Robert Bosch G M B H Fa Recording tape
US3032436A (en) * 1960-11-18 1962-05-01 Metal Proc Co Inc Method and composition for plating by chemical reduction
US3119709A (en) * 1956-09-28 1964-01-28 Atkinson Lab Inc Material and method for electroless deposition of metal

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Publication number Priority date Publication date Assignee Title
DE717547C (en) * 1938-05-03 1942-02-17 Dr Phil Willy Pragst Process for producing a firmly adhering, compact nickel mirror on glass or other non-conductors
US2430581A (en) * 1944-11-29 1947-11-11 Rca Corp Metallizing nonmetallic bodies
US2547838A (en) * 1947-11-26 1951-04-03 Russell Edward Wriothes Curzon Record bearing medium and methods of preparation
US2808345A (en) * 1953-04-23 1957-10-01 Robert Bosch G M B H Fa Recording tape
US2801935A (en) * 1953-09-30 1957-08-06 Merck & Co Inc The use of hydrazine tartrate salts in the chemical deposition of metals
US3119709A (en) * 1956-09-28 1964-01-28 Atkinson Lab Inc Material and method for electroless deposition of metal
US3032436A (en) * 1960-11-18 1962-05-01 Metal Proc Co Inc Method and composition for plating by chemical reduction

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3470074A (en) * 1964-08-18 1969-09-30 Siemag Siegener Masch Bau Depositing zinc coatings
US3416955A (en) * 1965-01-13 1968-12-17 Clevite Corp Electroless cobalt plating bath
US3500927A (en) * 1968-02-16 1970-03-17 Shell Oil Co Electroless metalization of unconsolidated earth formations
US3915716A (en) * 1969-04-17 1975-10-28 Schering Ag Chemical nickel plating bath
US4590095A (en) * 1985-06-03 1986-05-20 General Electric Company Nickel coating diffusion bonded to metallized ceramic body and coating method
US4780342A (en) * 1987-07-20 1988-10-25 General Electric Company Electroless nickel plating composition and method for its preparation and use
EP0525282A2 (en) * 1991-06-24 1993-02-03 Shipley Company Inc. Controlled electroless plating
EP0525282A3 (en) * 1991-06-24 1994-01-19 Shipley Co
US5622877A (en) * 1993-03-02 1997-04-22 Ramot University Authority For Applied Research & Industrial Development Ltd. Method for making high-voltage high-speed gallium arsenide power Schottky diode
WO2017134282A1 (en) 2016-02-05 2017-08-10 Technische Universität München Joining of components by means of energetically activated reactive particles

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