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Raney nickel

September 13, 2023

Not to be confused with Rieke nickel.

Raney nickel /ˈrn ˈnɪkəl/, also called spongy nickel,[1] is a fine-grained solid composed mostly of nickel derived from a nickel–aluminium alloy.[2][3] Several grades are known, of which most are gray solids. Some are pyrophoric, but most are used as air-stable slurries. Raney nickel is used as a reagent and as a catalyst in organic chemistry. It was developed in 1926 by American engineer Murray Raney for the hydrogenation of vegetable oils.[4][5] Raney is a registered trademark of W. R. Grace and Company. Other major producers are Evonik and Johnson Matthey.

Raney nickel

Dry activated Raney nickel
Identifiers
  • 7440-02-0 Y
UNII
  • 7OV03QG267 Y
Properties
Appearance Light-gray powder
Hazards
GHS labelling:
H250, H317, H351, H372, H412
P210, P273, P280, P302
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

Preparation Edit

Alloy preparation Edit

 
Raney nickel is pyrophoric and must be handled with care. This shipping container is filled with vermiculite to protect the sealed bottle inside.

The Ni–Al alloy is prepared by dissolving nickel in molten aluminium followed by cooling ("quenching"). Depending on the Ni:Al ratio, quenching produces a number of different phases. During the quenching procedure, small amounts of a third metal, such as zinc or chromium, are added to enhance the activity of the resulting catalyst. This third metal is called a "promoter".[6] The promoter changes the mixture from a binary alloy to a ternary alloy, which can lead to different quenching and leaching properties during activation.

Activation Edit

In the activation process, the alloy, usually as a fine powder, is treated with a concentrated solution of sodium hydroxide.[3] The simplified leaching reaction is given by the following chemical equation:

2 Al + 2 NaOH + 6 H2O → 2 Na[Al(OH)4] + 3 H2

The formation of sodium aluminate (Na[Al(OH)4]) requires that solutions of high concentration of sodium hydroxide be used to avoid the formation of aluminium hydroxide, which otherwise would precipitate as bayerite.[6] Hence sodium hydroxide solutions with concentrations of up to 5 M are used.

The temperature used to leach the alloy has a marked effect on the properties of the catalyst. Commonly, leaching is conducted between 70 and 100 °C. The surface area of Raney nickel (and related catalysts in general) tends to decrease with increasing leaching temperature.[7] This is due to structural rearrangements within the alloy that may be considered analogous to sintering, where alloy ligaments would start adhering to each other at higher temperatures, leading to the loss of the porous structure.[citation needed]

During the activation process, Al is leached out of the NiAl3 and Ni2Al3 phases that are present in the alloy, while most of the Ni remains, in the form of NiAl. The removal of Al from some phases but not others is known as "selective leaching". The NiAl phase has been shown to provide the structural and thermal stability of the catalyst. As a result, the catalyst is quite resistant to decomposition ("breaking down", commonly known as "aging").[7] This resistance allows Raney nickel to be stored and reused for an extended period; however, fresh preparations are usually preferred for laboratory use.[8] For this reason, commercial Raney nickel is available in both "active" and "inactive" forms.

Before storage, the catalyst can be washed with distilled water at ambient temperature to remove remaining sodium aluminate. Oxygen-free (degassed) water is preferred for storage to prevent oxidation of the catalyst, which would accelerate its aging process and result in reduced catalytic activity.[6]

Properties Edit

 
Phase diagram of the Ni–Al system, showing relevant phases
 
SEM of Raney nickel catalyst in which crystals of 1-50µm are seen.
 
A close-up of Raney nickel. Small cracks of approximately 1-100 nm width are seen within the crystals, causing the increased surface area.

Macroscopically, Raney nickel is a finely divided, grey powder. Microscopically, each particle of this powder is a three-dimensional mesh, with pores of irregular size and shape, the vast majority of which are created during the leaching process. Raney nickel is notable for being thermally and structurally stable, as well as having a large Brunauer-Emmett-Teller (BET ) surface area. These properties are a direct result of the activation process and contribute to a relatively high catalytic activity.[citation needed]

The surface area is typically determined by a BET measurement using a gas that is preferentially adsorbed on metallic surfaces, such as hydrogen. Using this type of measurement, almost all the exposed area in a particle of the catalyst has been shown to have Ni on its surface.[6] Since Ni is the active metal of the catalyst, a large Ni surface area implies a large surface is available for reactions to occur simultaneously, which is reflected in an increased catalyst activity. Commercially available Raney nickel has an average Ni surface area of 100 m2 per gram of catalyst.[6]

A high catalytic activity, coupled with the fact that hydrogen is absorbed within the pores of the catalyst during activation, makes Raney nickel a useful catalyst for many hydrogenation reactions. Its structural and thermal stability (i.e., it does not decompose at high temperatures) allows its use under a wide range of reaction conditions.[9][10] Additionally, the solubility of Raney nickel is negligible in most common laboratory solvents, with the exception of mineral acids such as hydrochloric acid, and its relatively high density (about 6.5 g cm−3)[1] also facilitates its separation from a liquid phase after a reaction is completed.

Applications Edit

Raney nickel is used in a large number of industrial processes and in organic synthesis because of its stability and high catalytic activity at room temperature.[6][11][12]

Industrial applications Edit

In a commercial application, Raney nickel is used as a catalyst for the hydrogenation of benzene to cyclohexane. Other heterogeneous catalysts, such as those using platinum group elements are used in some cases. Platinum metals tend to be more active, requiring milder temperatures, but they are more expensive than Raney nickel.[13] The cyclohexane thus produced may be used in the synthesis of adipic acid, a raw material used in the industrial production of polyamides such as nylon.[14]

 
using Raney nickel catalyzes the hydrogenation benzene to cyclohexane for the production of nylon precursors.

Other industrial applications of Raney nickel include the conversion of:

Applications in organic synthesis Edit

Desulfurization Edit

Raney nickel is used in organic synthesis for desulfurization. For example, thioacetals will be reduced to hydrocarbons in the last step of the Mozingo reduction:[14][15]

 
Example of desulfurization of thioacetals using Raney nickel

Thiols,[16] and sulfides[17] can be removed from aliphatic, aromatic, or heteroaromatic compounds. Likewise, Raney nickel will remove the sulfur of thiophene to give a saturated alkane.[18]

 
Reduction of thiophene by Raney nickel

Reduction of functional groups Edit

See also: Reduction of nitro compounds

It is typically used in the reduction of compounds with multiple bonds, such as alkynes, alkenes,[19] nitriles,[20] dienes, aromatics[21] and carbonyl-containing compounds. Additionally, Raney nickel will reduce heteroatom-heteroatom bonds, such as hydrazines,[22] nitro groups, and nitrosamines.[23] It has also found use in the reductive alkylation of amines[24] and the amination of alcohols.

When reducing a carbon-carbon double bond, Raney nickel will add hydrogen in a syn fashion.[14]

Related catalysts Edit

Raney cobalt has also been described.

In contrast to the pyrophoric nature of some forms of Raney nickel, nickel silicide-based catalysts represent potentially safer alternatives.[25]

Safety Edit

 
Raney nickel is flammable.
 
Nickel metal is classified as "Harmful".

Due to its large surface area and high volume of contained hydrogen gas, dry, activated Raney nickel is a pyrophoric material that requires handling under an inert atmosphere. Raney nickel is typically supplied as a 50% slurry in water. Even after reaction, residual Raney nickel contains significant amounts of hydrogen gas and may spontaneously ignite when exposed to air.[26]

Additionally, acute exposure to Raney nickel may cause irritation of the respiratory tract and nasal cavities, and causes pulmonary fibrosis if inhaled. Ingestion may lead to convulsions and intestinal disorders. It can also cause eye and skin irritation. Chronic exposure may lead to pneumonitis and other signs of sensitization to nickel, such as skin rashes ("nickel itch").[27]

NFPA 704
fire diamond
 Health 1: Exposure would cause irritation but only minor residual injury. E.g. turpentineFlammability 3: Liquids and solids that can be ignited under almost all ambient temperature conditions. Flash point between 23 and 38 °C (73 and 100 °F). E.g. gasolineInstability 1: Normally stable, but can become unstable at elevated temperatures and pressures. E.g. calciumSpecial hazards (white): no code
1
3
1

Nickel is also rated as being a possible human carcinogen by the IARC (Group 2B, EU category 3) and teratogen, while the inhalation of fine aluminium oxide particles is associated with Shaver's disease.

Development Edit

Murray Raney graduated as a mechanical engineer from the University of Kentucky in 1909. In 1915 he joined the Lookout Oil and Refining Company in Tennessee and was responsible for the installation of electrolytic cells for the production of hydrogen which was used in the hydrogenation of vegetable oils. During that time the industry used a nickel catalyst prepared from nickel(II) oxide. Believing that better catalysts could be produced, around 1921 he started to perform independent research while still working for Lookout Oil. In 1924 a 1:1 ratio Ni/Si alloy was produced, which after treatment with sodium hydroxide, was found to be five times more active than the best catalyst used in the hydrogenation of cottonseed oil. A patent for this discovery was issued in December 1925.[28]

Subsequently, Raney produced a 1:1 Ni/Al alloy following a procedure similar to the one used for the nickel-silicon catalyst. He found that the resulting catalyst was even more active and filed a patent application in 1926.[29] This is now a common alloy composition for modern Raney nickel catalysts.[2] Other common alloy compositions include 21:29 Ni/Al and 3:7 Ni/Al. Both the activity and preparation protocols for these catalysts vary.[2][30]

Following the development of Raney nickel, other alloy systems with aluminium were considered, of which the most notable include copper, ruthenium and cobalt.[31] Further research showed that adding a small amount of a third metal to the binary alloy would promote the activity of the catalyst. Some widely used promoters are zinc, molybdenum and chromium. An alternative way of preparing enantioselective Raney nickel has been devised by surface adsorption of tartaric acid.[32]

See also Edit

References Edit

  1. ^ a b "Spongy Nickel". European Space Agency.
  2. ^ a b c d Nishimura, Shigeo (2001). Handbook of Heterogeneous Catalytic Hydrogenation for Organic Synthesis (1st ed.). New York: Wiley-Interscience. pp. 7–19. ISBN 9780471396987.
  3. ^ a b Billica, Harry; Adkins, Homer (1949). "Cataylst, Raney Nickel, W6 (with high contents of aluminum and adsorbed hydrogen)". Organic Syntheses. 29: 24. doi:10.15227/orgsyn.029.0024.; Collective Volume, vol. 3, p. 176
  4. ^ See:
    • Raney, Murray, "Method of producing finely-divided nickel," 5 March 2017 at the Wayback Machine U.S. patent 1,628,190 (filed: 14 May 1926 ; issued: 10 May 1927).
    • M. S. Wainwright, "3.2 Skeletal metal catalysts" in: Gerhard Ertl, Helmut Knözinger, and Jens Weitkamp, ed.s, Preparaton of Solid Catalysts (Weinheim, Federal Republic of Germany: Wiley-VCH Verlag, 1999), pages 28–29.
  5. ^ Yang, Teng-Kuei; Lee, Dong-Sheng; Haas, Julia (2005). "Raney Nickel". Encyclopedia of Reagents for Organic Synthesis. New York: John Wiley & Sons. doi:10.1002/047084289X.rr001.pub2. ISBN 0471936235.
  6. ^ a b c d e f Ertl, Gerhard; Knözinger, Helmut (1997). Preparation of Solid Catalysts. Wiley. pp. 30–34. ISBN 3-527-29826-6.
  7. ^ a b Smith, A.J.; Trimm, D.L. (2005). "The preparation of skeletal catalysts". Annu. Rev. Mater. Res. 35: 127. doi:10.1146/annurev.matsci.35.102303.140758.
  8. ^ M. Guisnet, ed. (1993). Heterogeneous catalysis and fine chemicals III: proceedings of the 3rd international symposium. Elsevier. p. 69. ISBN 0-444-89063-7.
  9. ^ Crawford, Gerald (April 2003). "Exotic Alloy Finds Niche". Nickel magazine. Retrieved 19 December 2006.
  10. ^ Carruthers, W (1986). Some modern methods of organic synthesis. Cambridge University Press. pp. 413–414. ISBN 0-521-31117-9.
  11. ^ Hauptmann, Heinrich; Walter, Wolfgang Ferdinand (1962). "The Action of Raney Nickel on Organic Sulfur Compounds". Chem. Rev. 62 (5): 347. doi:10.1021/cr60219a001.
  12. ^ . 2005. Archived from the original on 5 June 2009. Retrieved 1 August 2009.
  13. ^ Campbell, M. Larry (2011). "Cyclohexane". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a08_209.pub2.
  14. ^ a b c Solomons, T.W. Graham; Fryhle, Craig B. (2004). Organic Chemistry. Wiley. ISBN 0-471-41799-8.
  15. ^ Jonathan Clayden; Nick Greeves; Stuart Warren (2012). Organic Chemistry (2 ed.). Oxford University Press. ISBN 9780199270293.
  16. ^ Graham, A. R.; Millidge, A. F.; Young, D. P. (1954). "Oxidation products of diisobutylene. Part III. Products from ring-opening of 1,2-epoxy-2,4,4-trimethylpentane". Journal of the Chemical Society (Resumed): 2180. doi:10.1039/JR9540002180.
  17. ^ Gassman, P. G.; van Bergen, T. J. (1988). "Indoles from anilines: Ethyl 2-methylindole-5-carboxylate". Organic Syntheses. doi:10.15227/orgsyn.056.0072.; Collective Volume, vol. 6, p. 601
  18. ^ Hoegberg, Hans Erik; Hedenstroem, Erik; Faegerhag, Jonas; Servi, Stefano (1992). "Bakers' yeast reduction of thiophenepropaenals. Enantioselective synthesis of (S)-2-methyl-1-alkanols via bakers' yeast mediated reduction of 2-methyl-3-(2-thiophene)propenals". J. Org. Chem. 57 (7): 2052–2059. doi:10.1021/jo00033a028.
  19. ^ Page, G. A.; Tarbell, D. S. (1963). "β-(o-Carboxyphenyl)propionic acid". Organic Syntheses. 34: 8. doi:10.15227/orgsyn.034.0008.; Collective Volume, vol. 4, p. 136
  20. ^ Robinson, H. C.; Snyder, H. R. (1955). "β-Phenylethylamine". Organic Syntheses. 23: 71. doi:10.15227/orgsyn.023.0071.; Collective Volume, vol. 3, p. 720
  21. ^ Schwenk, E.; Papa, D.; Hankin, H.; Ginsberg, H. (1955). "γ-n-Propylbutyrolactone and β-(Tetrahydrofuryl)propionic acid". Organic Syntheses. 27: 68. doi:10.15227/orgsyn.027.0068.; Collective Volume, vol. 3, p. 742
  22. ^ Alexakis, Alex; Lensen, Nathalie; Mangeney, Pierre (1991). "Ultrasound-Assisted Cleavage of N-N Bonds in Hydrazines by Raney Nickel". Synlett. 1991 (9): 625–626. doi:10.1055/s-1991-20818.
  23. ^ Enders, D.; Pieter, R.; Renger, B.; Seebach, D. (1988). "Nucleophilic α-sec-aminoalkylation: 2-(diphenylhydroxymethyl)pyrrolidene". Organic Syntheses. 58: 113. doi:10.15227/orgsyn.058.0113.; Collective Volume, vol. 6, p. 542
  24. ^ Rice, R. G.; Kohn, E. J. (1963). "N,N'-Diethylbenzidene". Organic Syntheses. 36: 21. doi:10.15227/orgsyn.036.0021.; Collective Volume, vol. 4, p. 283
  25. ^ P. Ryabchuk, G. Agostini, M.-M. Pohl, H. Lund, A. Agapova, H. Junge, K. Junge and M. Beller, Sci. Adv., 2018, 4, eaat0761, https://www.science.org/doi/10.1126/sciadv.aat0761
  26. ^ Armour, M.-A (2003). Hazardous laboratory chemicals disposal guide. CRC Press. p. 331. ISBN 1-56670-567-3.
  27. ^ "Nickel aluminide MSDS" (PDF). Electronic Space Products International. 1994.[permanent dead link]
  28. ^ US 1563587, Murray Raney, "Method of Preparing Catalytic Material", issued 1925-12-01  (Raney's original nickel-silicon catalyst)
  29. ^ US 1628190, Murray Raney, "Method of Producing Finely-Divided Nickel", issued 1927-05-10 
  30. ^ Urushibara, Yoshiyuki; Nishimura, Shigeo (1957). "A Method for the Preparation of the Raney Nickel Catalyst with a Greater Activity". Bull. Chem. Soc. Jpn. 30 (2): 199. doi:10.1246/bcsj.30.199.
  31. ^ Augustine, Robert L. (1996). Heterogeneous catalysis for the synthetic chemist. CRC Press. pp. 248–249. ISBN 0-8247-9021-9.
  32. ^ Bakker, M. L.; Young, D. J.; Wainwright, M. S. (1988). "Selective leaching of NiAl3 and Ni2Al3 intermetallics to form Raney nickels". J. Mater. Sci. 23 (11): 3921–3926. doi:10.1007/BF01106814. S2CID 95576771.

External links Edit

  • International Chemical Safety Card 0062
  • NIOSH Pocket Guide to Chemical Hazards
  • 1941 paper describing the preparation of W-2 grade Raney nickel: Mozingo, Ralph (1941). "Catalyst, Raney Nickel, W-2". Organic Syntheses. 21: 15. doi:10.15227/orgsyn.021.0015.

September 13, 2023
raney, nickel, confused, with, rieke, nickel, also, called, spongy, nickel, fine, grained, solid, composed, mostly, nickel, derived, from, nickel, aluminium, alloy, several, grades, known, which, most, gray, solids, some, pyrophoric, most, used, stable, slurri. Not to be confused with Rieke nickel Raney nickel ˈ r eɪ n iː ˈ n ɪ k el also called spongy nickel 1 is a fine grained solid composed mostly of nickel derived from a nickel aluminium alloy 2 3 Several grades are known of which most are gray solids Some are pyrophoric but most are used as air stable slurries Raney nickel is used as a reagent and as a catalyst in organic chemistry It was developed in 1926 by American engineer Murray Raney for the hydrogenation of vegetable oils 4 5 Raney is a registered trademark of W R Grace and Company Other major producers are Evonik and Johnson Matthey Raney nickel Dry activated Raney nickelIdentifiersCAS Number 7440 02 0 YUNII 7OV03QG267 YPropertiesAppearance Light gray powderHazardsGHS labelling PictogramsHazard statements H250 H317 H351 H372 H412Precautionary statements P210 P273 P280 P302Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references Contents 1 Preparation 1 1 Alloy preparation 1 2 Activation 2 Properties 3 Applications 3 1 Industrial applications 3 2 Applications in organic synthesis 3 2 1 Desulfurization 3 2 2 Reduction of functional groups 4 Related catalysts 5 Safety 6 Development 7 See also 8 References 9 External linksPreparation EditAlloy preparation Edit nbsp Raney nickel is pyrophoric and must be handled with care This shipping container is filled with vermiculite to protect the sealed bottle inside The Ni Al alloy is prepared by dissolving nickel in molten aluminium followed by cooling quenching Depending on the Ni Al ratio quenching produces a number of different phases During the quenching procedure small amounts of a third metal such as zinc or chromium are added to enhance the activity of the resulting catalyst This third metal is called a promoter 6 The promoter changes the mixture from a binary alloy to a ternary alloy which can lead to different quenching and leaching properties during activation Activation Edit In the activation process the alloy usually as a fine powder is treated with a concentrated solution of sodium hydroxide 3 The simplified leaching reaction is given by the following chemical equation 2 Al 2 NaOH 6 H2O 2 Na Al OH 4 3 H2The formation of sodium aluminate Na Al OH 4 requires that solutions of high concentration of sodium hydroxide be used to avoid the formation of aluminium hydroxide which otherwise would precipitate as bayerite 6 Hence sodium hydroxide solutions with concentrations of up to 5 M are used The temperature used to leach the alloy has a marked effect on the properties of the catalyst Commonly leaching is conducted between 70 and 100 C The surface area of Raney nickel and related catalysts in general tends to decrease with increasing leaching temperature 7 This is due to structural rearrangements within the alloy that may be considered analogous to sintering where alloy ligaments would start adhering to each other at higher temperatures leading to the loss of the porous structure citation needed During the activation process Al is leached out of the NiAl3 and Ni2Al3 phases that are present in the alloy while most of the Ni remains in the form of NiAl The removal of Al from some phases but not others is known as selective leaching The NiAl phase has been shown to provide the structural and thermal stability of the catalyst As a result the catalyst is quite resistant to decomposition breaking down commonly known as aging 7 This resistance allows Raney nickel to be stored and reused for an extended period however fresh preparations are usually preferred for laboratory use 8 For this reason commercial Raney nickel is available in both active and inactive forms Before storage the catalyst can be washed with distilled water at ambient temperature to remove remaining sodium aluminate Oxygen free degassed water is preferred for storage to prevent oxidation of the catalyst which would accelerate its aging process and result in reduced catalytic activity 6 Properties Edit nbsp Phase diagram of the Ni Al system showing relevant phases nbsp SEM of Raney nickel catalyst in which crystals of 1 50µm are seen nbsp A close up of Raney nickel Small cracks of approximately 1 100 nm width are seen within the crystals causing the increased surface area Macroscopically Raney nickel is a finely divided grey powder Microscopically each particle of this powder is a three dimensional mesh with pores of irregular size and shape the vast majority of which are created during the leaching process Raney nickel is notable for being thermally and structurally stable as well as having a large Brunauer Emmett Teller BET surface area These properties are a direct result of the activation process and contribute to a relatively high catalytic activity citation needed The surface area is typically determined by a BET measurement using a gas that is preferentially adsorbed on metallic surfaces such as hydrogen Using this type of measurement almost all the exposed area in a particle of the catalyst has been shown to have Ni on its surface 6 Since Ni is the active metal of the catalyst a large Ni surface area implies a large surface is available for reactions to occur simultaneously which is reflected in an increased catalyst activity Commercially available Raney nickel has an average Ni surface area of 100 m2 per gram of catalyst 6 A high catalytic activity coupled with the fact that hydrogen is absorbed within the pores of the catalyst during activation makes Raney nickel a useful catalyst for many hydrogenation reactions Its structural and thermal stability i e it does not decompose at high temperatures allows its use under a wide range of reaction conditions 9 10 Additionally the solubility of Raney nickel is negligible in most common laboratory solvents with the exception of mineral acids such as hydrochloric acid and its relatively high density about 6 5 g cm 3 1 also facilitates its separation from a liquid phase after a reaction is completed Applications EditRaney nickel is used in a large number of industrial processes and in organic synthesis because of its stability and high catalytic activity at room temperature 6 11 12 Industrial applications Edit In a commercial application Raney nickel is used as a catalyst for the hydrogenation of benzene to cyclohexane Other heterogeneous catalysts such as those using platinum group elements are used in some cases Platinum metals tend to be more active requiring milder temperatures but they are more expensive than Raney nickel 13 The cyclohexane thus produced may be used in the synthesis of adipic acid a raw material used in the industrial production of polyamides such as nylon 14 nbsp using Raney nickel catalyzes the hydrogenation benzene to cyclohexane for the production of nylon precursors Other industrial applications of Raney nickel include the conversion of Dextrose to sorbitol Nitro compounds to amines for example 2 4 dinitrotoluene to 2 4 toluenediamine Nitriles to amines for example stearonitrile to stearylamine and adiponitrile to hexamethylenediamine Olefins to paraffins for example sulfolene to sulfolane Acetylenes to paraffins for example 1 4 butynediol to 1 4 butanediol Applications in organic synthesis Edit Desulfurization Edit Raney nickel is used in organic synthesis for desulfurization For example thioacetals will be reduced to hydrocarbons in the last step of the Mozingo reduction 14 15 nbsp Example of desulfurization of thioacetals using Raney nickelThiols 16 and sulfides 17 can be removed from aliphatic aromatic or heteroaromatic compounds Likewise Raney nickel will remove the sulfur of thiophene to give a saturated alkane 18 nbsp Reduction of thiophene by Raney nickelReduction of functional groups Edit See also Reduction of nitro compounds It is typically used in the reduction of compounds with multiple bonds such as alkynes alkenes 19 nitriles 20 dienes aromatics 21 and carbonyl containing compounds Additionally Raney nickel will reduce heteroatom heteroatom bonds such as hydrazines 22 nitro groups and nitrosamines 23 It has also found use in the reductive alkylation of amines 24 and the amination of alcohols When reducing a carbon carbon double bond Raney nickel will add hydrogen in a syn fashion 14 Related catalysts EditRaney cobalt has also been described In contrast to the pyrophoric nature of some forms of Raney nickel nickel silicide based catalysts represent potentially safer alternatives 25 Safety Edit nbsp Raney nickel is flammable nbsp Nickel metal is classified as Harmful Due to its large surface area and high volume of contained hydrogen gas dry activated Raney nickel is a pyrophoric material that requires handling under an inert atmosphere Raney nickel is typically supplied as a 50 slurry in water Even after reaction residual Raney nickel contains significant amounts of hydrogen gas and may spontaneously ignite when exposed to air 26 Additionally acute exposure to Raney nickel may cause irritation of the respiratory tract and nasal cavities and causes pulmonary fibrosis if inhaled Ingestion may lead to convulsions and intestinal disorders It can also cause eye and skin irritation Chronic exposure may lead to pneumonitis and other signs of sensitization to nickel such as skin rashes nickel itch 27 NFPA 704fire diamond nbsp 131Nickel is also rated as being a possible human carcinogen by the IARC Group 2B EU category 3 and teratogen while the inhalation of fine aluminium oxide particles is associated with Shaver s disease Development EditMurray Raney graduated as a mechanical engineer from the University of Kentucky in 1909 In 1915 he joined the Lookout Oil and Refining Company in Tennessee and was responsible for the installation of electrolytic cells for the production of hydrogen which was used in the hydrogenation of vegetable oils During that time the industry used a nickel catalyst prepared from nickel II oxide Believing that better catalysts could be produced around 1921 he started to perform independent research while still working for Lookout Oil In 1924 a 1 1 ratio Ni Si alloy was produced which after treatment with sodium hydroxide was found to be five times more active than the best catalyst used in the hydrogenation of cottonseed oil A patent for this discovery was issued in December 1925 28 Subsequently Raney produced a 1 1 Ni Al alloy following a procedure similar to the one used for the nickel silicon catalyst He found that the resulting catalyst was even more active and filed a patent application in 1926 29 This is now a common alloy composition for modern Raney nickel catalysts 2 Other common alloy compositions include 21 29 Ni Al and 3 7 Ni Al Both the activity and preparation protocols for these catalysts vary 2 30 Following the development of Raney nickel other alloy systems with aluminium were considered of which the most notable include copper ruthenium and cobalt 31 Further research showed that adding a small amount of a third metal to the binary alloy would promote the activity of the catalyst Some widely used promoters are zinc molybdenum and chromium An alternative way of preparing enantioselective Raney nickel has been devised by surface adsorption of tartaric acid 32 See also EditNickel aluminide Urushibara nickel Rieke nickel Nickel boride catalyst Raney cobalt a similar cobalt aluminum alloy catalyst which is sometimes more selective for certain hydrogenation products e g primary amines via nitrile reduction 2 References Edit a b Spongy Nickel European Space Agency a b c d Nishimura Shigeo 2001 Handbook of Heterogeneous Catalytic Hydrogenation for Organic Synthesis 1st ed New York Wiley Interscience pp 7 19 ISBN 9780471396987 a b Billica Harry Adkins Homer 1949 Cataylst Raney Nickel W6 with high contents of aluminum and adsorbed hydrogen Organic Syntheses 29 24 doi 10 15227 orgsyn 029 0024 Collective Volume vol 3 p 176 See Raney Murray Method of producing finely divided nickel Archived 5 March 2017 at the Wayback Machine U S patent 1 628 190 filed 14 May 1926 issued 10 May 1927 M S Wainwright 3 2 Skeletal metal catalysts in Gerhard Ertl Helmut Knozinger and Jens Weitkamp ed s Preparaton of Solid Catalysts Weinheim Federal Republic of Germany Wiley VCH Verlag 1999 pages 28 29 Yang Teng Kuei Lee Dong Sheng Haas Julia 2005 Raney Nickel Encyclopedia of Reagents for Organic Synthesis New York John Wiley amp Sons doi 10 1002 047084289X rr001 pub2 ISBN 0471936235 a b c d e f Ertl Gerhard Knozinger Helmut 1997 Preparation of Solid Catalysts Wiley pp 30 34 ISBN 3 527 29826 6 a b Smith A J Trimm D L 2005 The preparation of skeletal catalysts Annu Rev Mater Res 35 127 doi 10 1146 annurev matsci 35 102303 140758 M Guisnet ed 1993 Heterogeneous catalysis and fine chemicals III proceedings of the 3rd international symposium Elsevier p 69 ISBN 0 444 89063 7 Crawford Gerald April 2003 Exotic Alloy Finds Niche Nickel magazine Retrieved 19 December 2006 Carruthers W 1986 Some modern methods of organic synthesis Cambridge University Press pp 413 414 ISBN 0 521 31117 9 Hauptmann Heinrich Walter Wolfgang Ferdinand 1962 The Action of Raney Nickel on Organic Sulfur Compounds Chem Rev 62 5 347 doi 10 1021 cr60219a001 Raney nickel usage in Organic Syntheses 2005 Archived from the original on 5 June 2009 Retrieved 1 August 2009 Campbell M Larry 2011 Cyclohexane Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a08 209 pub2 a b c Solomons T W Graham Fryhle Craig B 2004 Organic Chemistry Wiley ISBN 0 471 41799 8 Jonathan Clayden Nick Greeves Stuart Warren 2012 Organic Chemistry 2 ed Oxford University Press ISBN 9780199270293 Graham A R Millidge A F Young D P 1954 Oxidation products of diisobutylene Part III Products from ring opening of 1 2 epoxy 2 4 4 trimethylpentane Journal of the Chemical Society Resumed 2180 doi 10 1039 JR9540002180 Gassman P G van Bergen T J 1988 Indoles from anilines Ethyl 2 methylindole 5 carboxylate Organic Syntheses doi 10 15227 orgsyn 056 0072 Collective Volume vol 6 p 601 Hoegberg Hans Erik Hedenstroem Erik Faegerhag Jonas Servi Stefano 1992 Bakers yeast reduction of thiophenepropaenals Enantioselective synthesis of S 2 methyl 1 alkanols via bakers yeast mediated reduction of 2 methyl 3 2 thiophene propenals J Org Chem 57 7 2052 2059 doi 10 1021 jo00033a028 Page G A Tarbell D S 1963 b o Carboxyphenyl propionic acid Organic Syntheses 34 8 doi 10 15227 orgsyn 034 0008 Collective Volume vol 4 p 136 Robinson H C Snyder H R 1955 b Phenylethylamine Organic Syntheses 23 71 doi 10 15227 orgsyn 023 0071 Collective Volume vol 3 p 720 Schwenk E Papa D Hankin H Ginsberg H 1955 g n Propylbutyrolactone and b Tetrahydrofuryl propionic acid Organic Syntheses 27 68 doi 10 15227 orgsyn 027 0068 Collective Volume vol 3 p 742 Alexakis Alex Lensen Nathalie Mangeney Pierre 1991 Ultrasound Assisted Cleavage of N N Bonds in Hydrazines by Raney Nickel Synlett 1991 9 625 626 doi 10 1055 s 1991 20818 Enders D Pieter R Renger B Seebach D 1988 Nucleophilic a sec aminoalkylation 2 diphenylhydroxymethyl pyrrolidene Organic Syntheses 58 113 doi 10 15227 orgsyn 058 0113 Collective Volume vol 6 p 542 Rice R G Kohn E J 1963 N N Diethylbenzidene Organic Syntheses 36 21 doi 10 15227 orgsyn 036 0021 Collective Volume vol 4 p 283 P Ryabchuk G Agostini M M Pohl H Lund A Agapova H Junge K Junge and M Beller Sci Adv 2018 4 eaat0761 https www science org doi 10 1126 sciadv aat0761 Armour M A 2003 Hazardous laboratory chemicals disposal guide CRC Press p 331 ISBN 1 56670 567 3 Nickel aluminide MSDS PDF Electronic Space Products International 1994 permanent dead link US 1563587 Murray Raney Method of Preparing Catalytic Material issued 1925 12 01 Raney s original nickel silicon catalyst US 1628190 Murray Raney Method of Producing Finely Divided Nickel issued 1927 05 10 Urushibara Yoshiyuki Nishimura Shigeo 1957 A Method for the Preparation of the Raney Nickel Catalyst with a Greater Activity Bull Chem Soc Jpn 30 2 199 doi 10 1246 bcsj 30 199 Augustine Robert L 1996 Heterogeneous catalysis for the synthetic chemist CRC Press pp 248 249 ISBN 0 8247 9021 9 Bakker M L Young D J Wainwright M S 1988 Selective leaching of NiAl3 and Ni2Al3 intermetallics to form Raney nickels J Mater Sci 23 11 3921 3926 doi 10 1007 BF01106814 S2CID 95576771 External links EditInternational Chemical Safety Card 0062 NIOSH Pocket Guide to Chemical Hazards 1941 paper describing the preparation of W 2 grade Raney nickel Mozingo Ralph 1941 Catalyst Raney Nickel W 2 Organic Syntheses 21 15 doi 10 15227 orgsyn 021 0015 Retrieved from https en wikipedia org w index php title Raney nickel amp oldid 1151878384, wikipedia, wiki, book, books, library,

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