Nickel boride catalyst

Nickel boride is the common name of materials composed chiefly of the elements nickel and boron that are widely used as catalysts in organic chemistry.[1][2] Their approximate chemical composition is Ni2.5B,[3] and they are often incorrectly denoted "Ni
2
B
" in organic chemistry publications.

Nickel boride catalysts are typically prepared by reacting a salt of nickel with sodium borohydride. The composition and properties vary depending on the specific preparation method. The two most common forms, described and evaluated in detail by Herbert C. Brown and Charles Allan Brown in 1963, are known as P−1 nickel[4][5] and P−2 nickel.[6][7]

These catalysts are usually obtained as black granules (P−1) or colloidal suspensions (P−2).[8] They are air-stable, non-magnetic and non-pyrophoric,[5] but slowly react with water to form nickel hydroxide Ni(OH)
2
.[3] They are insoluble in all solvents, but react with concentrated mineral acids.[1] They are claimed to be more effective hydrogenation catalysts than Raney nickel.[5]

History

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These catalysts originate during World War II with the work of a research group led by Hermann I. Schlesinger, discoverer of borohydrides. They noted that reaction of NaBH
4
with salts of certain transition metals yielded black precipitates, and that the cobalt product catalyzed the decomposition of borohydride. However, their research was focused on war-related applications, and the black precipitate was not investigated further.[9]

In 1951, Raymond Paul and others investigated the reaction of NaBH
4
with nickel chloride, sulfate, and acetate in various solvents and measured their performance as hydrogenation catalysts.[10]

In 1963, H. C. Brown and Charles A. Brown reported the synthesis and performance of two similar catalysts, which they denoted by "P-1" (the same as Paul's) and "P-2", obtained by reacting sodium borohydride with nickel acetate in water and ethanol, respectively.[4][6]

Preparation

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In contrast with other borides, which require high temperatures, preparation of these nickel boride catalysts can be carried out at ambient temperature, without special equipment.[11] Indeed, they are usually generated in situ.[1]

The P−1 catalyst can be generated by reacting a nickel(II) salt, such as sulfate, chloride, nitrate, or acetate, and sodium borohydride in alkaline aqueous solutions.[5] The product precipitates as a fine, black granular powder.[5][3] The chemistry is very similar to that of electroless nickel-boron plating, and yields hydrogen gas and the corresponding sodium salt as byproducts.[5] The borohydride must be added gradually to the nickel salt solution, not the other way around, because the product catalyzes the hydrolysis of borohydride to hydrogen and hypoborate BO
2
.[10] The catalytic activity of P-1 is enhanced by adding small amount of salts of other metals (but not cobalt) to the nickel salt during preparation.[10] Benzene however reduces its activity somewhat.[5]

The P−2 form is prepared similarly from nickel(II) acetate and sodium borohydride in ethanol. An inert atmosphere was found necessary for maximum catalytic activity. The result was an almost colloidal suspension of the black catalyst.[7] Another method uses nickel chloride NiCl2 instead of acetate.[1]

Structure and composition

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The P-1 and P-2 "nickel boride" catalyst have been suggested to be amorphous compounds, composed of nickel bonded to individual boron centres.[11] However, that structure was later found to be incorrect.

An X-ray diffraction analysis of P-1 by L. Hofer and others in 1964 indicated that the nickel and boron contents were in 2.5:1 ratio, but the solid contained 11% of strongly bound water and other compounds. was amorphous when freshly prepared (with crystalline nanoparticles about 1.5 nm across), but even heating at 90 °C caused the formation of some crystalline nickel. Heating at 250 °C caused it to separate into two phases: metallic nickel, and crystalline trinickel boride Ni
3
B
with the cementite structure, stable at least up to 750 C. No trace of the true dinickel boride Ni
2
B
was seen. The authors concluded that P-1 was an intimate mixture of metallic nickel and some amorphous boron-containing compound.[3]

The true structure of these "nickel borides" was elucidated only in 2007. They consist of small grains of crystalline nickel boride embedded in an amorphous nickel matrix.[12]

The two forms P−1 and P−2 differ in terms of amount of their contamination by NaBO2 adsorbed on the surface. P−1 Ni2B has an oxide to boride ratio of 1:4, whereas that of P−2 Ni2B is 10:1. Their properties differ in terms of catalytic efficiency and substrate specificity.[1]

Applications

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Ni2B is an efficient catalyst and reducing agent. It is used as a heterogeneous hydrogenation catalyst.

Catalytic hydrogenation

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The catalytic activity of P−1 is insensitive to steric hindrance of side chains on the substrate and thus more active, and seldom affects protecting groups. In contrast, P−2 is very sensitive to steric factors.[1] For these reasons, P−1 is usually used for the complete reduction of unsaturated hydrocarbons under mild conditions, while P−2 is useful in partial reductions such as converting alkynes to alkenes in high yields:[13]

 

The H2/Ni2B system will not hydrogenolyse ethers, alcohols, aldehydes, amines and amides as it reduces alkenes in preference, even under forcing conditions. It leaves epoxides unaffected, but affects cyclopropanes occasionally. Most esters are stable to Ni2B, except for benzylic, allylic and propargylic esters which are cleaved by hydrogenolysis:[1]

 

Desulfurization

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The NiCl2/NaBH4 system desulfurizes thioamides, thioethers, thioesters, thiols and sulfides. Organic sulfides, disulfides, thiols, and sulfoxides are reduced by NiCl2/NaBH4 to hydrocarbons. Illustrated is the reduction of phenothiazine to diphenylamine:

 

Ni2B can also be used to cleave thioacetals. Since Ni2B is non-pyrophoric, stable in air, and give high yields in many cases, it is proposed as a safer alternative to Raney Nickel for removal of cyclic thioacetals. Desulfurization catalyzed by Ni2B proved to occur with retention of configuration by isotopic labeling.[1]

Reduction of nitrogenous groups

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The NiCl2/NaBH4 system reduces aliphatic nitro groups, nitriles and oximes completely to amines. For aryl amines, nitrobenzenes are converted to anilines, and azoxybenzenes to azobenzenes. Azides are cleanly reduced to amines in preference to sterically hindered aliphatic nitro groups:[1]

 

Dehalogenation

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Most organic fluorides and chlorides are unaffected by Ni2B, bromides show variable reactivity, and iodides are often completely reduced to hydrocarbons. With Ni2B in dimethylformamide, α-bromoketones are reduced to the parent ketones. Vicinal bromides are dehalogenated to alkenes:

 

For aryl bromides, the modified system Ni(PPh3)3Cl2/NaBH4 in dimethylformamide is used for clean debromination. Reductive cleavage of iodides occurs with retention of configuration.[1]

Safety

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Nickel compounds are possible carcinogens and contact with skin should be avoided. Particular care should be taken whenever NiCl2/NaBH4 is used in dimethylformamide as sodium borohydride may spontaneously ignite in dimethylformamide.

See also

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References

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  1. ^ a b c d e f g h i j Steven D. Burke; Rick L. Danheiser (1999). "Nickel boride". Handbook of Reagents for Organic Synthesis, Oxidizing and Reducing Agents. Wiley. p. 246. ISBN 978-0-471-97926-5.
  2. ^ Robert A. Scott (2011). "Boron: Inorganic Chemistry". Encyclopedia of Inorganic Chemistry. Wiley. p. 401. ISBN 9780470862100.
  3. ^ a b c d L. J. E. Hofer, J. F. Shultz, R. D. Panson, and R. B. Anderson (1964): "The nature of the nickel boride formed by the action of sodium borohydride on nickel salts". Inorganic Chemistry, volume 3, issue 12, pages 1783–1785. doi:10.1021/ic50022a031
  4. ^ a b Charles A. Brown and Herbert C. Brown (1963): "The reaction of sodium borohydride with nickel acetate in aqueous solution—a convenient synthesis of a nickel hydrogenation catalyst of low isomerization tendency". Journal of the American Chemical Society (Communications to the Editor), volume 85, issue 7, pages 1003-1005. doi:10.1021/ja00890a040
  5. ^ a b c d e f g Charles Allan Brown (1970): "Catalytic hydrogenation. V. Reaction of sodium borohydride with aqueous nickel salts. P-1 nickel boride, a convenient, highly active nickel hydrogenation catalyst". The Journal of Organic Chemistry, volume 35, issue 6, pages 1900–1904. doi:10.1021/jo00831a039
  6. ^ a b Herbert C. Brown and Charles A. Brown (1963): "The reaction of sodium borohydride with nickel acetate in ethanol solution: a highly selective nickel hydrogenation catalyst". Journal of the American Chemical Society (Communications to the Editor), volume 85, issue 7, pages 1005-1006. doi:10.1021/ja00890a041
  7. ^ a b Charles Allan Brown and Vijay K. Ahuja (1973): "Catalytic hydrogenation. VI. Reaction of sodium borohydride with nickel salts in ethanol solution. P-2 Nickel, a highly convenient, new, selective hydrogenation catalyst with great sensitivity to substrate structure". Journal of Organic Chemistry, volume 38, issue 12, pages 2226–2230. doi:10.1021/jo00952a024
  8. ^ Chemicals & Reagents, 2008-2010
  9. ^ Hermann Irving Schlesinger, Herbert C. Brown, A. E. Finholt, James R. Gilbreath, Henry R. Hoekstra, and Earl K. Hyde (1953): "Sodium borohydride its hydrolysis and its use as a reducing agent and in the generation of hydrogen". Journal of the American Chemical Society, volume 75, issue 1,pages 215-219. doi:10.1021/ja01097a057
  10. ^ a b c Raymond Paul, Paul Buisson, and Nicole Joseph (1952): "Catalytic activity of nickel borides". Industrial and Engineering Chemistry, volume 44, issue 5, pages 1006-1010. doi:10.1021/ie50509a029
  11. ^ a b Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. p. 147. ISBN 978-0-08-037941-8.
  12. ^ Geng, J.; Jefferson, D.A.; Johnson, B.F.G. (2007). "The unusual nanostructure of nickel–boron catalyst". Chemical Communications (9): 969–971. doi:10.1039/B615529D. PMID 17311137.
  13. ^ T. W. Graham Solomons; Craig Fryhle (2007). Organic Chemistry, 9th Edition. Wiley. p. 361. ISBN 978-0-471-68496-1.