Copper(II) chlorate

Copper(II) chlorate is a chemical compound of the transition metal copper and the chlorate anion with basic formula Cu(ClO3)2. Copper chlorate is an oxidiser.[3] It commonly crystallizes with four molecules of water.

Copper(II) chlorate
Names
IUPAC name
Copper(2+) chlorate hydrate (1:2:4)
Other names
Copper(II) chlorate; Cupric chlorate
Identifiers
3D model (JSmol)
ChemSpider
ECHA InfoCard 100.035.228
EC Number
  • 238-767-0
UNII
UN number 2721
Properties
Cu(ClO3)2•4H2O
Molar mass 302.509
Appearance Light blue
Density 2.26 g cm3
Melting point 73 °C
Boiling point decomposes
highly water-soluble
Structure[1]
Orthorhombic
Pcab
mmm
a = 12.924, b = 9.502, c = 7.233[2]
Å
888.3Å3
3
distorted octahedral
Hazards
Main hazards oxidiser
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Infobox references

Production

Copper chlorate can be made by combining a hot one molar solution of copper sulfate, with barium chlorate, which results in the precipitation of barium sulfate. When the solution is filtered, cooled and evaporated under a vacuum blue crystals form.[4]

CuSO4 + Ba(ClO3)2 Cu(ClO3)2 + BaSO4(s)

Properties

In 1902 A Meusser investigated solubility of copper chlorate. He found that it melted and started decomposing above 73 °C giving off chlorine.[5]

Hexaaquacopper(II) chlorate Cu(ClO3)2•6H2O has a molecular weight of 338.54 and melts at 65 °C. Its solubility in water in g/100ml at different temperatures: 141 (0 °C) 164.4 (18 °C) 195.6 (45 °C) 332 (70 °C) g/100ml. It also dissolves in acetone and ethanol[6]

Tetraaquacopper(II) chlorate has an orthorhombic crystal structure with cell dimensions a=12.924 b=9.502 c=7.233 Å, V = 888.3Å3, Density = 2.26 g cm-3.[2] Each copper atom is octahedrally coordinated, surrounded by four oxygen atoms of water, and two oxygen atoms from chlorate groups, which are opposite each other. Water is closer to the copper than clorate, 1.944 Å compared to 2.396 Å, exhibiting the Jahn-Teller effect. The chlorate groups take the shape of a distorted tetrahedron. In chlorate at 298 K (25 °C) the chlorine oxygen distances are 1.498, 1.488 and 1.468 Å, with the longest being the oxygen next to copper. The ∠O-Cu-O (angle subtended at copper by oxygen atoms) is 105.2°, 108.3°, and 106.8°. At lower temperatures 233 K (−40 °C) the water molecules and copper-chlorate distance shrink.[2]

Tetraaquacopper(II) chlorate solubility in water -31 °C 54.59 -21° 57.12 0.8° 58.51 18° 62.17 45° 66.17 59.6° 69.42 71° 76.9 g/100ml of solution A saturated water solution at 18° has a density of 1.695 g·cm−3.[7][8]

Copper chlorate decomposes when heated, giving off a yellow gas, which contains chlorine, oxygen and chlorine dioxide.[9] A green solid is left that is a basic copper salt.[10]

2Cu(ClO3)2 2CuO + Cl2 + 3O2 + 2ClO2

Sulfur is highly reactive with copper chlorate, and it is important not to cross contaminate these chemicals, for example in pyrotechnic making.[11]

Use

François-Marie Chertier used tetrammine copper chlorate to colour flames blue in 1843. This material was abbreviated TACC with formula Cu(NH3)4(ClO3)2. TACC explodes on impact.[12]

The substance became known as Chertier'c copper for use in blue coloured pyrotechnics.[13] However its deliquescence causes a problem.[14] Mixtures with other metal salts can yield violet or lilac colours also.[15]

It has also been used to colour copper brown.[16]

gollark: That is not the issue.
gollark: <@175686996461617162> When you upgrade, keep the existing CPU in sonething and overclock until it melts.
gollark: And I bet for the price you can get six cores now.
gollark: Given:- smaller process node (easier to add more stuff, increase clock)- faster RAM- faster IO- simultaneous multithreading- other generic IPC improvements- probably bigger or at least faster cache- higher clocksit's inevitable.
gollark: I'd say, in fact, that a modern dual core would beat it.

References

  1. "CuH8(ClO5)2". Materials Project. doi:10.17188/1286535.
  2. Blackburn, A. C.; Gallucci, J. C.; Gerkin, R. E. (1 August 1991). "Structure of tetraaquacopper(II) chlorate at 296 and 223 K". Acta Crystallographica Section B. B47: 474–479. doi:10.1107/S0108768191000435. ISSN 0108-7681. PMID 1930830.
  3. Lewis, Richard J. (2008). Hazardous Chemicals Desk Reference. John Wiley & Sons. p. 384. ISBN 9780470334454.
  4. Suhara, Masahiko (April 1973). "The Temperature Dependence of the Nuclear Quadrupole Resonance of 35Cl in KClO3, AgClO3, Ba(ClO3)2·H2 O, and Cu(ClO3) 2·6H2O". Bulletin of the Chemical Society of Japan. 46 (4): 1053–1055. doi:10.1246/bcsj.46.1053.
  5. Meusser, A. (April 1902). "Metallchlorate. Studien über die Löslichkeit der Salze. X" (PDF). Berichte der deutschen chemischen Gesellschaft. 35 (2): 1414–1424. doi:10.1002/cber.19020350240.
  6. "copper(II) chlorate hexahydrate". chemister.ru.
  7. Seidell, Atherton (1919). A. Solubilities of inorganic and organic compounds. - 3ed., vol.1 (PDF) (2 ed.). New York: D. Van Nostrand Company. p. 264. Archived from the original (PDF) on 2018-02-03. Retrieved 2018-02-01.
  8. Woolley, E. M.; Miyamoto, H.; Salomon, M. (1990). Copper and Silver Halates (PDF). Elsevier. ISBN 9781483286051.
  9. Rosenstiehl, A. (September 1876). "The Theory of Formation of Aniline Black". Journal of the Chemical Society. London. 30 (165): 311.
  10. Waechter, M. Alexander (30 April 2009). "On the preparation and properties of certain chlorates". Philosophical Magazine. 3rd Series. 25 (165): 235–237. doi:10.1080/14786444408644978.
  11. Bretherick, L. (1990). Bretherick's Handbook of Reactive Chemical Hazards. Butterworths. p. 975. ISBN 9780750601030.
  12. Kosanke, K. L.; Sturman, Barry T.; Winokur, Robert M.; Kosanke, B. J. (2012). Encyclopedic Dictionary of Pyrotechnics: (and Related Subjects). Journal of Pyrotechnics. p. 1107. ISBN 9781889526218.
  13. Browne, W. H. (1873). The art of pyrotechny. London: The Bazaar. p. 35.
  14. Thorpe, Sir Thomas Edward (1924). A Dictionary of Applied Chemistry. Longmans, Green, and Company. p. 520.
  15. Hiscox, G. D. (1931). Henley's twentieth century formulas, recipes and processes. Рипол Классик. pp. 609–610. ISBN 9785876347008.
  16. Krause, Hugo (1938). Metal coloring and finishing: latest practical methods for coloring and finishing metals of all kinds. Chemical publishing co. of N. Y., inc. p. 96.
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