Copper(I) chloride explained

Copper(I) chloride, commonly called cuprous chloride, is the lower chloride of copper, with the formula CuCl. The substance is a white solid sparingly soluble in water, but very soluble in concentrated hydrochloric acid. Impure samples appear green due to the presence of copper(II) chloride (CuCl₂).

History

Copper(I) chloride was first prepared by Robert Boyle in the mid-seventeenth century from mercury(II) chloride ("Venetian sublimate") and copper metal:^[1]

HgCl₂ + 2 Cu → 2 CuCl + Hg

In 1799, J.L. Proust characterized the two different chlorides of copper. He prepared CuCl by heating CuCl₂ at red heat in the absence of air, causing it to lose half of its combined chlorine followed by removing residual CuCl₂ by washing with water.^[2]

An acidic solution of CuCl was formerly used to analyze carbon monoxide content in gases, for example in Hempel's gas apparatus where the CuCl absorbs the carbon monoxide.^[3] This application was significant during the nineteenth and early twentieth centuries when coal gas was widely used for heating and lighting.^[4]

Synthesis

Copper(I) chloride is produced industrially by the direct combination of copper metal and chlorine at 450–900 °C:^{[5] [6]}

Copper(I) chloride can also be prepared by reducing copper(II) chloride with sulfur dioxide, or with ascorbic acid (vitamin C) that acts as a reducing sugar:^{[7] [8]}

Many other reducing agents can be used.

Properties

Copper(I) chloride has the cubic zincblende crystal structure at ambient conditions. Upon heating to 408 °C the structure changes to hexagonal. Several other crystalline forms of CuCl appear at high pressures (several GPa).

Copper(I) chloride is a Lewis acid. It is classified as soft according to the hard-soft acid-base concept. Thus, it forms a series of complexes with soft Lewis bases such as triphenylphosphine:

CuCl + 1 P(C₆H₅)₃ → 1/4 ₄

CuCl + 2 P(C₆H₅)₃ → CuCl[P(C₆H₅)₃)]₂

CuCl + 3 P(C₆H₅)₃ → CuCl[P(C₆H₅)₃)]₃

CuCl also forms complexes with halides. For example H₃O⁺ CuCl₂⁻ forms in concentrated hydrochloric acid.^[9] Chloride is displaced by CN⁻ and S₂O₃²⁻.

Solutions of CuCl in HCl absorb carbon monoxide to form colourless complexes such as the chloride-bridged dimer [CuCl(CO)]₂. The same hydrochloric acid solutions also react with acetylene gas to form [CuCl(C₂H₂)]. Ammoniacal solutions of CuCl react with acetylenes to form the explosive copper(I) acetylide, Cu₂C₂. Alkene complexes of CuCl can be prepared by reduction of CuCl₂ by sulfur dioxide in the presence of the alkene in alcohol solution. Complexes with dienes such as 1,5-cyclooctadiene are particularly stable:^[10]

Upon contact with water, copper(I) chloride slowly undergoes disproportionation:

2 CuCl → Cu + CuCl₂In part for this reason, samples in air assume a green coloration.^[11]

Uses

The main use of copper(I) chloride is as a precursor to the fungicide copper oxychloride. For this purpose aqueous copper(I) chloride is generated by comproportionation and then air-oxidized:

Cu + CuCl₂ → 2 CuCl

4 CuCl + O₂ + 2 H₂O → Cu₃Cl₂(OH)₄ + CuCl₂

Copper(I) chloride catalyzes a variety of organic reactions, as discussed above. Its affinity for carbon monoxide in the presence of aluminium chloride is exploited in the COPure^SM process.^[12]

In organic synthesis

CuCl is used as a co-catalyst with carbon monoxide, aluminium chloride, and hydrogen chloride in the Gatterman-Koch reaction to form benzaldehydes.^[13]

In the Sandmeyer reaction, the treatment of an arenediazonium salt with CuCl leads to an aryl chloride. For example:^{[14] [15]}

The reaction has wide scope and usually gives good yields.

Early investigators observed that copper(I) halides catalyse 1,4-addition of Grignard reagents to alpha,beta-unsaturated ketones^[16] led to the development of organocuprate reagents that are widely used today in organic synthesis:^[17]

This finding led to the development of organocopper chemistry. For example, CuCl reacts with methyllithium (CH₃Li) to form "Gilman reagents" such as (CH₃)₂CuLi, which find use in organic synthesis. Grignard reagents form similar organocopper compounds. Although other copper(I) compounds such as copper(I) iodide are now more often used for these types of reactions, copper(I) chloride is still recommended in some cases:^[18]

Cuprous chloride also catalyzes the dimerization of acetylene to vinylacetylene, once used as a precursor to various polymers such a neoprene.^[19]

Niche uses

CuCl is used as a catalyst in atom transfer radical polymerization (ATRP). It is also used in pyrotechnics as a blue/green coloring agent. In a flame test, copper chlorides, like all copper compounds, emit green-blue.^[20]

Natural occurrence

Natural form of CuCl is the rare mineral nantokite.^{[21] [22]}

See also

Copper(II) chloride

External links

• National Pollutant Inventory – Copper and compounds fact sheet
• The COPure^SM Process for purifying CO utilizing a copper chloride complex

Notes and References

1. Book: Boyle, Robert. Considerations and experiments about the origin of forms and qualities. 1666. Oxford. 286–288.
2. Proust. J. L.. Ann. Chim. Phys. . 1799. 32. 26–54. Recherches sur le Cuivre.
3. Book: Martin, Geoffrey. 1922. Industrial and Manufacturing Chemistry. Part 1, Organic. London. Crosby Lockwood. 408.
4. Lewes. Vivian H.. Journal of the Society of Chemical Industry. 1891. The Analysis of Illuminationg Gases. 10. 407–413.
5. Book: Richardson, H. W.. Kirk-Othmer Encyclopedia of Chemical Technology. 2003. 0471238961. Copper Compounds. 10.1002/0471238961.0315161618090308.a01.pub2.
6. Book: Ullmann's Encyclopedia of Industrial Chemistry. Zhang, J. . Richardson, H. W.. 2016. 978-3-527-30673-2. Copper Compounds. 1–31 . 10.1002/14356007.a07_567.pub2.
7. Book: Glemser . O. . Sauer . H. . 1963 . Copper(I) Chloride . Handbook of Preparative Inorganic Chemistry . 2nd . G. . Brauer . Academic Press . New York . 1 . 1005 .
8. Tuğba Akbıyık . İnci Sönmezoğlu . Kubilay Güçlü . İzzet Tor . Reşat Apak . Protection of Ascorbic Acid from Copper(II)−Catalyzed Oxidative Degradation in the Presence of Fruit Acids: Citric, Oxalic, Tartaric, Malic, Malonic, and Fumaric Acids . International Journal of Food Properties . 2012 . 15 . 2 . 398–411 . 10.1080/10942912.2010.487630 . 85408826 . en.
9. J. J. Fritz . Chloride complexes of copper(I) chloride in aqueous solution . J. Phys. Chem. . 1980 . 84 . 18 . 2241–2246 . 10.1021/j100455a006 . en.
10. Nicholls, D. (1973) Complexes and First-Row Transition Elements, Macmillan Press, London.
11. Pastor, Antonio C. (1986) "Method of preparing cupric ion free cuprous chloride" Section 2, lines 4–41.
12. Xiaozhou Ma . Jelco Albertsma . Dieke Gabriels . Rens Horst . Sevgi Polat . Casper Snoeks . Freek Kapteijn . Hüseyin Burak Eral . David A. Vermaas . Bastian Mei . Sissi de Beer . Monique Ann van der Veen . Carbon monoxide separation: past, present and future . Chemical Society Reviews . 2023 . 52 . 11 . 3741–3777 . 10.1039/D3CS00147D . 37083229 . 10243283 . en.
13. Dilke. M. H.. Eley. D. D.. 1949. 550. The Gattermann–Koch reaction. Part II. Reaction kinetics. J. Chem. Soc.. en. 2613–2620. 10.1039/JR9490002613. 0368-1769.
14. Wade, L. G. (2003) Organic Chemistry, 5th ed., Prentice Hall, Upper Saddle River, New Jersey, p. 871. .
15. March, J. (1992) Advanced Organic Chemistry, 4th ed., Wiley, New York. p. 723.
16. Factors Determining the Course and Mechanisms of Grignard Reactions. II. The Effect of Metallic Compounds on the Reaction between Isophorone and Methylmagnesium Bromide . . 63 . 2308 . 1941 . 10.1021/ja01854a005 . Kharasch, M. S. . Tawney, P. O. . 9.
17. Jasrzebski, J. T. B. H.; van Koten, G. (2002) Modern Organocopper Chemistry, N. Krause (ed.). Wiley-VCH, Weinheim, Germany. p. 1. .
18. Bertz, S. H.; Fairchild, E. H. (1999) Handbook of Reagents for Organic Synthesis, Volume 1: Reagents, Auxiliaries and Catalysts for C-C Bond Formation, R. M. Coates, S. E. Denmark (eds.). Wiley, New York. pp. 220–3. .
19. 10.1021/cr400357r . Catalytic Reactions of Acetylene: A Feedstock for the Chemical Industry Revisited . 2014 . Trotuş . Ioan-Teodor . Zimmermann . Tobias . Schüth . Ferdi . Chemical Reviews . 114 . 3 . 1761–1782 . 24228942 . free .
20. Barrow . R F . Caldin . E F . 1949-01-01 . Some Spectroscopic Observations on Pyrotechnic Flames . Proceedings of the Physical Society. Section B . 62 . 1 . 32–39 . 10.1088/0370-1301/62/1/305 . 0370-1301.
21. Web site: Nantokite.
22. Web site: List of Minerals. 21 March 2011.