Gold(III) chloride explained

Gold(III) chloride, traditionally called auric chloride, is an inorganic compound of gold and chlorine with the molecular formula . The "III" in the name indicates that the gold has an oxidation state of +3, typical for many gold compounds. It has two forms, the monohydrate (AuCl3·H2O) and the anhydrous form, which are both hygroscopic and light-sensitive solids. This compound is a dimer of . This compound has a few uses, such as an oxidizing agent and for catalyzing various organic reactions.

Structure

exists as a chloride-bridged dimer both as a solid and vapour, at least at low temperatures.[1] Gold(III) bromide behaves analogously. The structure is similar to that of iodine(III) chloride.

Each gold center is square planar in gold(III) chloride, which is typical of a metal complex with a d8 electron count. The bonding in is considered somewhat covalent.

Properties

Gold(III) chloride is a diamagnetic light-sensitive red crystalline solid that forms the orange monohydrate, AuCl3 · H2O; the anhydrous and monohydrate are both hygroscopic. The anhydrous form absorbs moisture from the air to form the monohydrate which can be reversed by the addition of thionyl chloride.

Preparation

Gold(III) chloride was first prepared in 1666 by Robert Boyle by the reaction of metallic gold and chlorine gas at 180 °C:[2] [3] [4]

This method is the most common method of preparing gold(III) chloride. It can also be prepared by reacting gold powder with iodine monochloride:

2 Au + 6 ICl → 2 AuCl3 + 3 I2

The chlorination reaction can be conducted in the presence of tetrabutylammonium chloride, the product being the lipophilic salt tetrabutylammonium tetrachloraurate.[5]

Another method of preparation is via chloroauric acid, which is obtained by first dissolving the gold powder in aqua regia to give chloroauric acid:[6]

The resulting chloroauric acid is subsequently heated in an inert atmosphere at around 100 °C to give :[7]

Reactions

Decomposition

Anhydrous begins to decompose to AuCl (gold(I) chloride) at around, however, this, in turn, undergoes disproportionation at higher temperatures to give gold metal and AuCl3:[8]

(160 °C)

(>210 °C)Due to the disproportionation of AuCl, above 210 °C, most of the gold is in the form of elemental gold.[9] [10]

Gold(III) chloride is more stable in a chlorine atmosphere and can sublime at around 200 °C without any decomposition. In a chlorine atmosphere, AuCl3 decomposes at 254 °C yielding AuCl which in turn decomposes at 282 °C to elemental gold.[11] This fact that no gold chlorides can exist above 400 °C is used in the Miller process.[12]

Other reactions

is a Lewis acid and readily forms complexes. For example, it reacts with hydrochloric acid to form chloroauric acid :

Chloroauric acid is the product formed when gold dissolves in aqua regia.

On contact with water, forms acidic hydrates and the conjugate base . A ion may reduce it, causing elemental gold to be precipitated from the solution.[2] [13]

Other chloride sources, such as KCl, also convert into . Aqueous solutions of react with an aqueous base such as sodium hydroxide to form a precipitate of, which will dissolve in excess NaOH to form sodium aurate . If gently heated, decomposes to gold(III) oxide,, and then to gold metal.[14] [15] [16] [17]

Gold(III) chloride is the starting point for the chemical synthesis of many other gold compounds. For example, the reaction with potassium cyanide produces the water-soluble complex, :[18]

Gold(III) fluoride can be also produced from gold(III) chloride by reacting it with bromine trifluoride.

Gold(III) chloride reacts with benzene under mild conditions (reaction times of a few minutes at room temperature) to produce the dimeric phenylgold(III) dichloride; a variety of other arenes undergo a similar reaction:[19]

Gold(III) chloride reacts with carbon monoxide in a variety of ways. For example, the reaction of anhydrous AuCl3 and carbon monoxide under SOCl2 produces gold(I,III) chloride with Au(CO)Cl as an intermediate:[20] [21]

2 AuCl3 + 2 CO → Au4Cl8 + 2 COCl2If carbon monoxide is in excess, Au(CO)Cl is produced instead.[22]

However, under tetrachloroethylene and at 120 °C, gold(III) chloride is first reduced to gold(I) chloride, which further reacts to form Au(CO)Cl. AuCl3 is also known to catalyze the production of phosgene.[23] [24]

Applications

Although gold(III) chloride has no commercial uses, it has many uses in the laboratory.

Organic synthesis

Since 2003, has attracted the interest of organic chemists as a mild acid catalyst for various reactions,[25] although no transformations have been commercialised. Gold(III) salts, especially , provide an alternative to mercury(II) salts as catalysts for reactions involving alkynes. An illustrative reaction is the hydration of terminal alkynes to produce acetyl compounds.[26]

Gold catalyses the alkylation of certain aromatic rings and the conversion of furans to phenols. Some alkynes undergo amination in the presence of gold(III) catalysts. For example, a mixture of acetonitrile and gold(III) chloride catalyses the alkylation of 2-methylfuran by methyl vinyl ketone at the 5-position:

The efficiency of this organogold reaction is noteworthy because both the furan and the ketone are sensitive to side reactions such as polymerisation under acidic conditions. In some cases where alkynes are present, phenols sometimes form (Ts is an abbreviation for tosyl):[27]

This reaction involves a rearrangement that gives a new aromatic ring.[28]

Another example of an AuCl3 catalyzed reaction is a hydroarylation, which is basically a Friedel-Crafts reaction using metal-alkyne complexes. Example, the reaction of mesitylene with phenylacetylene:[29]

Gold(III) chloride can be used for the direct oxidation of primary amines into ketones, such as the oxidation of cyclohexylamine to cyclohexanone.

This reaction is pH sensitive, requiring a mildly acidic pH to proceed, however, it does not require any additional steps.

In the production of organogold(III) compounds, AuCl3 is used as a source of gold. A main example of this is the production of monoarylgold(III) complexes, which are produced by direct electrophilic auration of arenes by gold(III) chloride.[30]

Gold nanoparticles

Gold(III) chloride is used in the synthesis of gold nanoparticles, which are extensively studied for their unique size-dependent properties and applications in fields such as electronics, optics, and biomedicine. Gold nanoparticles can be prepared by reducing gold(III) chloride with a reducing agent such as sodium tetrafluoroborate, followed by stabilization with a capping agent.[31]

Photography

Gold(III) chloride has been used historically in the photography industry as a sensitizer in the production of photographic films and papers. However, with the advent of digital photography, its use in this field has diminished.[32]

Natural occurrence

This compound does not occur naturally; however, a similar compound with the formula AuO(OH,Cl)·nH2O is known as a product of natural gold oxidation.[33] [34]

Notes and References

  1. E. S. Clark . D. H. Templeton . C. H. MacGillavry . 1958 . The crystal structure of gold(III) chloride . . 11 . 4. 284–288 . 10.1107/S0365110X58000694 . 2010-05-21. free .
  2. Book: Egon Wiberg . Nils Wiberg . A. F. Holleman . 2001 . Inorganic Chemistry. 101 . Academic Press. 978-0-12-352651-9. 1286–1287.
  3. Book: Robert Boyle . Robert Boyle . The origine of formes and qualities . 1666 . 370 . en.
  4. Thomas Kirke Rose . The dissociation of chloride of gold . Journal of the Chemical Society, Transactions . 1895 . 67 . 881–904 . 10.1039/CT8956700881 . en.
  5. 10.1071/C97029. Reduction of [NBu4][AuCl4] to [NBu4][AuCl2] with Sodium Acetylacetonate. 1997. Buckley. Robbie W.. Healy. Peter C.. Loughlin. Wendy A.. Australian Journal of Chemistry. 50. 7. 775.
  6. Book: 10.1002/9780470132357.ch4. Gold Powder and Potassium Tetrabromoaurate(III). Inorganic Syntheses. 1953. 4. Block. B. P.. Inorganic Syntheses . 14–17. 9780470132357.
  7. Ya-jie Zheng . Wei Guo . Meng Bai . Xing-wen Yang . Preparation of chloroauric acid and its thermal decomposition . The Chinese Journal of Nonferrous Metals . 2006 . 16 . 11 . 1976–1982 . https://web.archive.org/web/20240327045836/http://ysxb.csu.edu.cn/previewFile?id=36231978&type=pdf&lang=en. March 27, 2024. chinese.
  8. Michael J. Coghlan . Rene-Viet Nguyen . Chao-Jun Li . Daniel Pflästerer . A. Stephen K. Hashmi . Gold(III) Chloride . Encyclopedia of Reagents for Organic Synthesis . 2015 . 1–24 . 10.1002/047084289X.rn00325.pub3. 9780470842898 .
  9. Yiqin Chen . Xuezeng Tian . Wei Zeng . Xupeng Zhu . Hailong Hu . Huigao Duan . Vapor-phase preparation of gold nanocrystals by chloroauric acid pyrolysis . Journal of Colloid and Interface Science . 2015 . 439 . 21–27 . 10.1016/j.jcis.2014.10.017 . Elsevier . 25463171 . 2015JCIS..439...21C . en.
  10. Robert G. Palgrave . Ivan P. Parkin . Aerosol Assisted Chemical Vapor Deposition of Gold and Nanocomposite Thin Films from Hydrogen Tetrachloroaurate(III) . Chemistry of Materials . 2007 . 19 . 19 . 4639–4647 . 10.1021/cm0629006 . ACS Publications . en.
  11. E.M.W. Janssen . J.C.W. Folmer . G.A. Wiegers . The preparation and crystal structure of gold monochloride, AuCl . Journal of the Less Common Metals . 1974 . 38 . 1 . 71–76 . 10.1016/0022-5088(74)90204-5 . en.
  12. Book: Ullmann's Encyclopedia of Industrial Chemistry. Hermann Renner . Günther Schlamp. 2000. 978-3-527-30673-2. Gold, Gold Alloys, and Gold Compounds. 106–107 . 10.1002/14356007.a12_499.
  13. Cotton, F.A.; Wilkinson, G.; Murillo, C.A.; Bochmann, M. Advanced Inorganic Chemistry; John Wiley & Sons: New York, 1999; pp. 1101-1102
  14. Book: N. N. Greenwood . A. Earnshaw . Chemistry of the Elements . 1997 . . Oxford, UK . 9780750633659 . 1184–1185 . 2 . en.
  15. The Merck Index. An Encyclopaedia of Chemicals, Drugs and Biologicals. 14. Ed., 2006, p. 780, .
  16. H. Nechamkin, The Chemistry of the Elements, McGraw-Hill, New York, 1968, p. 222
  17. A. F. Wells, Structural Inorganic Chemistry, 5th ed., Oxford University Press, Oxford, UK, 1984, p. 909
  18. Henry K. Lutz . Synthesis and Analyses of KAu(CN)4 . Honors Theses. . 1961 . Union Digital Works . en.
  19. Li. Zigang. Brouwer. Chad. He. Chuan. 2008-08-01. Gold-Catalyzed Organic Transformations. Chemical Reviews. 108. 8. 3239–3265. 10.1021/cr068434l. 18613729. 0009-2665.
  20. Daniela Belli Dell'Amico . Fausto Calderazzo . Fabio Marchetti . Stefano Merlino . Giovanni Perego . X-Ray crystal and molecular structure of Au4Cl8, the product of the reduction of Au2Cl6 by Au(CO)Cl . Journal of the Chemical Society, Chemical Communications . 1977 . 31–32 . 10.1039/C39770000031 . en.
  21. Daniela Belli Dell'Amico . Fausto Calderazzo . Fabio Marchetti . Stefano Merlino . Synthesis and molecular structure of [Au4Cl8], and the isolation of [Pt(CO)Cl5]– in thionyl chloride . Journal of the Chemical Society, Dalton Transactions . 1982 . 11 . 2257–2260 . 10.1039/DT9820002257 . en.
  22. Book: Carbonylchlorogold(I) . 1986 . 24 . 236–238 . 10.1002/9780470132555.ch66 . Inorganic Syntheses . Dell'Amico . D. Belli . Calderazzo . F. . Murray . H. H. . John P. Fackler Jr. . Fackler . J. P. . 9780470132555 .
  23. Book: T.A. Ryan . E.A. Seddon . K.R. Seddon . C. Ryan . Phosgene And Related Carbonyl Halides . 1996 . Elsevier Science . 9780080538808 . 242–243 . en.
  24. M. S. Kharasch . H. S. Isbell . The Chemistry of Organic Gold Compounds. I. Aurous Chloride Carbonyl and a Method of Linking Carbon to Carbon . Journal of the American Chemical Society . 1930 . 52 . 7 . 2919–2927 . 10.1021/ja01370a052 . en.
  25. G. Dyker, An Eldorado for Homogeneous Catalysis?, in Organic Synthesis Highlights V, H.-G. Schmaltz, T. Wirth (eds.), pp 48–55, Wiley-VCH, Weinheim, 2003
  26. Y. Fukuda . K. Utimoto . Effective transformation of unactivated alkynes into ketones or acetals with a gold(III) catalyst . . 1991 . 56 . 11 . 10.1021/jo00011a058 . 3729.
  27. A. S. K. Hashmi . T. M. Frost . J. W. Bats . Highly Selective Gold-Catalyzed Arene Synthesis . . 2000 . 122 . 46 . 10.1021/ja005570d . 11553.
  28. A. Stephen . K. Hashmi . M. Rudolph . J. P. Weyrauch . M. Wölfle . W. Frey . J. W. Bats . Gold Catalysis: Proof of Arene Oxides as Intermediates in the Phenol Synthesis . Angewandte Chemie International Edition. 2005 . 44 . 18 . 10.1002/anie.200462672 . 2798–801 . 15806608.
  29. 10.1002/ejoc.200300260. Gold-Catalyzed Hydroarylation of Alkynes. European Journal of Organic Chemistry. 2003. 18. 3485–3496. 2003. Reetz . M. T. . Sommer . K. .
  30. Kharasch. M. S.. Isbell. Horace S.. The Chemistry of Organic Gold Compounds. III. Direct Introduction of Gold into the Aromatic Nucleus (Preliminary Communication). 1931-08-01. Journal of the American Chemical Society. 53. 8. 3053–3059. 10.1021/ja01359a030. 0002-7863.
  31. M. Lin . C. M. Sorensen . K. J. Klabunde . Ligand-Induced Gold Nanocrystal Superlattice Formation in Colloidal Solution . Chemistry of Materials . 1999 . 11 . 2 . 198–202 . 10.1021/cm980665o . en.
  32. Philip Ellis . Gold in photography . Gold Bulletin . 1975 . 8 . 7–12 . 10.1007/BF03215055 . 136538890 . en. free .
  33. Web site: UM1995-16-O:AuClH . mindat.org . 27 April 2023.
  34. John L. Jambor . Nikolai N. Pertsev . Andrew C. Roberts . New Mineral Names . American Mineralogist . 1996 . 81 . 768 . en.