Zinc chloride explained

Zinc chloride is an inorganic chemical compound with the formula ZnCl2·nH2O, with n ranging from 0 to 4.5, forming hydrates. Zinc chloride, anhydrous and its hydrates, are colorless or white crystalline solids, and are highly soluble in water. Five hydrates of zinc chloride are known, as well as four forms of anhydrous zinc chloride. All forms of zinc chloride are deliquescent. Zinc chloride finds wide application in textile processing, metallurgical fluxes, and chemical synthesis. In a major monograph, zinc chlorides have been described as "one of the important compounds of zinc."

Structure and properties

Relative to other metal dihalides, zinc dichloride is unusual in forming several crystalline forms (polymorphs). Four are known: α, β, γ, and δ. Each case features tetrahedral centers.[1]

Form a (nm) b (nm) c (nm) Z Density (g/cm3)
α tI12 I2d 122 0.5398 0.5398 0.64223 4 3.00
β tetragonal tP6 P42/nmc 137 0.3696 0.3696 1.071 2 3.09
γ mP36 P21/c 14 0.654 1.131 1.23328 12 2.98
δ oP12 Pna21 33 0.6125 0.6443 0.7693 4 2.98

Here a, b, and c are lattice constants, Z is the number of structure units per unit cell, and ρ is the density calculated from the structure parameters.[2] [3] [4]

The orthorhombic form (δ) rapidly changes to one of the other forms on exposure to the atmosphere. A possible explanation is that the ions originating from the absorbed water facilitate the rearrangement.[1] Rapid cooling of molten gives a glass.[5]

Molten has a high viscosity at its melting point and a comparatively low electrical conductivity, which increases markedly with temperature.[6] [7] As indicated by a Raman scattering study, the viscosity is explained by the presence of polymers,.[8] Neutron scattering study indicated the presence of tetrahedral centers, which requires aggregation of monomers as well.[9]

Hydrates

Various hydrates of zinc chloride are known: with n = 1, 1.33, 2.5, 3, and 4.5.[10] The 1.33-hydrate, previously thought to be the hemitrihydrate, consists of trans-Zn(H2O)4Cl2 centers with the chlorine atoms connected to repeating ZnCl4 chains. The hemipentahydrate, structurally formulated [Zn(H<sub>2</sub>O)<sub>5</sub>][ZnCl<sub>4</sub>], consists of Zn(H2O)5Cl octahedrons where the chlorine atom is part of a [ZnCl<sub>4</sub>]2- tetrahedera. The trihydrate consists of distinct hexaaquozinc(II) cations and tetrachlorozincate anions; formulated [Zn(H<sub>2</sub>O)<sub>6</sub>][ZnCl<sub>4</sub>]. Finally, the heminonahydrate, structurally formulated [Zn(H<sub>2</sub>O)<sub>6</sub>][ZnCl<sub>4</sub>]·3H2O also consists of distinct hexaaquozinc(II) cations and tetrachlorozincate anions like the trihydrate but has three extra water molecules.[11] [12]

Preparation and purification

Historically, zinc chlorides are prepared from the reaction of hydrochloric acid with zinc metal or zinc oxide. Aqueous acids cannot be used to produce anhydrous zinc chloride. According to an early procedure, a suspension of powdered zinc in diethyl ether is treated with hydrogen chloride, followed by drying[13] The overall method remains useful in industry, but without the solvent:

Aqueous solutions may be readily prepared similarly by treating Zn metal, zinc carbonate, zinc oxide, and zinc sulfide with hydrochloric acid:[14]

Hydrates can be produced by evaporation of an aqueous solution of zinc chloride. The temperature of the evaporation determines the hydrates For example, evaporation at room temperature produces the 1.33-hydrate.[15] Lower evaporation temperatures produce higher hydrates.

Commercial samples of zinc chloride typically contain water and products from hydrolysis as impurities. Laboratory samples may be purified by recrystallization from hot dioxane. Anhydrous samples can be purified by sublimation in a stream of hydrogen chloride gas, followed by heating the sublimate to 400 °C in a stream of dry nitrogen gas.[16] A simple method relies on treating the zinc chloride with thionyl chloride.[17]

Reactions

Chloride complexes

A number of salts containing the tetrachlorozincate anion,, are known.[6] "Caulton's reagent",, which is used in organic chemistry, is an example of a salt containing .[18] [19]

Notes and References

  1. Book: Wells, A. F. . 1984 . Structural Inorganic Chemistry . Oxford . Clarendon Press . 978-0-19-855370-0 .
  2. Oswald . H. R. . Jaggi . H. . Zur Struktur der wasserfreien Zinkhalogenide I. Die wasserfreien Zinkchloride . Helvetica Chimica Acta . 1960 . 43 . 1 . 72–77 . 10.1002/hlca.19600430109 .
  3. Brynestad . J. . Yakel . H. L. . Preparation and Structure of Anhydrous Zinc Chloride . Inorganic Chemistry . 1978 . 17 . 5 . 1376–1377 . 10.1021/ic50183a059 .
  4. Brehler . B. . Kristallstrukturuntersuchungen an ZnCl2 . Zeitschrift für Kristallographie . 1961 . 115 . 5–6 . 373–402 . 10.1524/zkri.1961.115.5-6.373 . 1961ZK....115..373B .
  5. Mackenzie, J. D. . Murphy, W. K. . Structure of Glass-Forming Halides. II. Liquid Zinc Chloride . The Journal of Chemical Physics . 1960 . 33 . 2 . 366–369 . 10.1063/1.1731151 . 1960JChPh..33..366M .
  6. Book: Prince, R. H. . 1994 . Encyclopedia of Inorganic Chemistry . King, R. B. . John Wiley & Sons . 978-0-471-93620-6 .
  7. Book: Ray, H. S. . 2006. Introduction to Melts: Molten Salts, Slags and Glasses . Allied Publishers . 978-81-7764-875-1 .
  8. Book: Danek, V. . 2006 . Physico-Chemical Analysis of Molten Electrolytes . Elsevier . 978-0-444-52116-3 .
  9. Price . D. L. . Saboungi . M.-L. . Susman . S. . Volin . K. J. . Wright . A. C. . Neutron Scattering Function of Vitreous and Molten Zinc Chloride . Journal of Physics: Condensed Matter . 1991 . 3 . 49 . 9835–9842 . 10.1088/0953-8984/3/49/001 . 1991JPCM....3.9835P . 250902741 .
  10. Book: Holleman, A. F. . Wiberg, E. . Inorganic Chemistry . Academic Press . San Diego . 2001 . 978-0-12-352651-9 .
  11. H. Follner . B. Brehler . Die Kristallstruktur des ZnCl2.4/3H2O . Acta Crystallographica B . 1970 . 26 . 11 . 1679–1682 . 10.1107/S0567740870004715 . 1970AcCrB..26.1679F . The crystal structure of ZnCl2.4/3H2O . de.
  12. E. Hennings . H. Schmidt . W. Voigt . Crystal structures of ZnCl2·2.5H2O, ZnCl2·3H2O and ZnCl2·4.5H2O . Acta Crystallographica E . 2014 . 70 . 12 . 515–518 . 10.1107/S1600536814024738 . 25552980 . en. 4257420 .
  13. 10.1039/JR9320002282 . Notes: The Preparation of Pure Zinc Chloride . 1932 . Hamilton . R. T. . Butler . J. A. V. . Journal of the Chemical Society (Resumed) . 2283–4 .
  14. Book: 10.1002/0471238961.2609140307151504.a02.pub3 . Zinc Compounds . Kirk-Othmer Encyclopedia of Chemical Technology . 2017 . Frank E. . Goodwin . 9–10 . 978-0-471-23896-6 .
  15. F. Mylius . R. Dietz . Über das Chlorzink. (Studien über die Löslichkeit der Salze XIV.) . Zeitschrift für anorganische Chemie . 1905 . 44 . 1 . 209–220 . 10.1002/zaac.19050440115 . en.
  16. 10.1002/047084289X.rz007.pub3. Zinc chloride. Glenn J. McGarvey Jean-François Poisson Sylvain Taillemaud. 2016. Encyclopedia of Reagents for Organic Synthesis. 1–20. 978-0-470-84289-8.
  17. Book: Pray, A. P. . Anhydrous Metal Chlorides. Inorganic Syntheses . 1990 . 28 . 321–322.
  18. Book: 3 . Mulzer, J. . Waldmann, H. . Organic Synthesis Highlights . 1998 . Wiley-VCH . 978-3-527-29500-5 .
  19. 10.1002/zaac.19976230163 . Difluorenylzink als Alkylierungsmittel zur Darstellung von Triorganometallanen der 13. Gruppe. Synthese und Kristallstruktur von [GaFl3(THF)] · Toluol (Fl = Fluorenyl) . 1997 . Dashti . Anahita . Niediek . Katharina . Werner . Bert . Neumüller . Bernhard . Zeitschrift für Anorganische und Allgemeine Chemie . 623 . 1–6 . 394–402 .
  20. Book: 10.1002/9780470132401.ch2. Dichlorobis(hydroxylamine)zinc(II) (Crismer's Salt). 1967. 9. Walker. John E.. Howell. David M.. Inorganic Syntheses. 2–3. 978-0-470-13240-1.
  21. Xu, Q. . Chen, L.-F. . Ultraviolet Spectra and Structure of Zinc-Cellulose Complexes in Zinc Chloride Solution . Journal of Applied Polymer Science . 1999 . 71 . 9 . 1441–1446 . 10.1002/(SICI)1097-4628(19990228)71:9<1441::AID-APP8>3.0.CO;2-G .
  22. Fischer . S. . Leipner . H. . Thümmler . K. . Brendler . E. . Peters . J. . Inorganic Molten Salts as Solvents for Cellulose . Cellulose . 2003 . 10 . 3 . 227–236 . 10.1023/A:1025128028462 . 92194004 .
  23. Yamaguchi . T. . Lindqvist . O. . The Crystal Structure of Diamminedichlorozinc(II), ZnCl2(NH3)2. A New Refinement . Acta Chemica Scandinavica A . 1981 . 35 . 9 . 727–728 . 10.3891/acta.chem.scand.35a-0727 . free .
  24. Book: Vulte, H. T. . Laboratory Manual of Inorganic Preparations . Read Books . 2007 . 978-1-4086-0840-1 .
  25. Yamaguchi . T. . Ohtaki . H. . X-Ray Diffraction Studies on the Structures of Tetraammine- and Triamminemonochlorozinc(II) Ions in Aqueous Solution . Bulletin of the Chemical Society of Japan . 1978 . 51 . 11 . 3227–3231 . 10.1246/bcsj.51.3227 . free .
  26. Irish . D. E. . McCarroll . B. . Young . T. F. . Raman Study of Zinc Chloride Solutions . The Journal of Chemical Physics . 1963 . 39 . 12 . 3436–3444 . 10.1063/1.1734212 . 1963JChPh..39.3436I .
  27. Yamaguchi . T. . Hayashi . S. . Ohtaki . H. . X-Ray Diffraction and Raman Studies of Zinc(II) Chloride Hydrate Melts, ZnCl2 · R H2O (R = 1.8, 2.5, 3.0, 4.0, and 6.2) . The Journal of Physical Chemistry . 1989 . 93 . 6 . 2620–2625 . 10.1021/j100343a074 .
  28. Pye, C. C. . Corbeil, C. R. . Rudolph, W. W. . An ab initio Investigation of Zinc Chloro Complexes . Physical Chemistry Chemical Physics . 2006 . 8 . 46 . 5428–5436 . 10.1039/b610084h . 1463-9076 . 17119651 . 2006PCCP....8.5428P . 37521287 .
  29. Book: Brown, I. D. . 2006 . The Chemical Bond in Inorganic Chemistry: The Bond Valence Model . Oxford University Press . 978-0-19-929881-5 .
  30. Kjonaas, R. A. . Riedford, B. A. . A Study of the Lucas Test . Journal of Chemical Education . 1991 . 68 . 8 . 704 . 10.1021/ed068p704 .
  31. Book: Zhang, X. G. . 1996 . Corrosion and Electrochemistry of Zinc . Springer . 978-0-306-45334-2 . Web site: Simonkolleite Mineral Data . Staff writer(s). webmineral.com . October 16, 2014.
  32. Feigl, F. . Caldas, A. . Some Applications of Fusion Reactions with Zinc Chloride in Inorganic Spot Test Analysis . Microchimica Acta . 1956 . 44 . 7–8 . 1310–1316 . 10.1007/BF01257465 . 96823985 .
  33. Book: Menzel, E. R. . 1999 . Fingerprint Detection with Lasers . CRC Press . 978-0-8247-1974-6 .
  34. Frida Jones . Honghi Tran . Daniel Lindberg . Liming Zhao . Mikko Hupa . Thermal Stability of Zinc Compounds . Energy & Fuels . 2013 . 27 . 10 . 5663–5669 . 10.1021/ef400505u . en.
  35. Book: F. Wagenknecht. R. Juza. Zinc Hydroxychloride. Handbook of Preparative Inorganic Chemistry, 2nd Ed. . G. Brauer. Academic Press. 1963. NY,NY. 2pages=1071.
  36. Book: House, J. E. . 2008 . Inorganic Chemistry . Academic Press . 978-0-12-356786-4 .
  37. Book: Wiberg, Nils. Lehrbuch der Anorganischen Chemie . Holleman & Wiberg, Textbook of Inorganic chemistry . de. de Gruyter, Berlin. 2007 . 1491. 978-3-11-017770-1.
  38. Hydrocarbons from Methanol. Clarence D.. Chang. 1–118. 10.1080/01614948308078874. Catal. Rev. - Sci. Eng.. 25. 1. 1983.
  39. Onium Ylide chemistry. 1. Bifunctional acid-base-catalyzed conversion of heterosubstituted methanes into ethylene and derived hydrocarbons. The onium ylide mechanism of the C1 → C2 conversion. George A.. Olah. Hans. Doggweiler. Jeff D.. Felberg. Stephan. Frohlich. Mary Jo. Grdina. Richard. Karpeles. Takashi. Keumi. Shin-ichi. Inaba. Wai M.. Ip. Koop. Lammertsma. George. Salem. Derrick. Tabor. J. Am. Chem. Soc.. 1984. 106. 7. 2143–2149. 10.1021/ja00319a039.
  40. Book: Furnell, B. S. . Vogel's Textbook of Practical Organic Chemistry . 5th . Longman/Wiley . New York . 1989 .
  41. Dike . S. Y. . Merchant . J. R. . Sapre . N. Y. . A New and Efficient General Method for the Synthesis of 2-Spirobenzopyrans: First Synthesis of Cyclic Analogues of Precocene I and Related Compounds . . 1991 . 47 . 26 . 4775–4786 . 10.1016/S0040-4020(01)86481-4 .
  42. Bauml, E. . Tschemschlok, K. . Pock, R. . Mayr, H. . Synthesis of γ-Lactones from Alkenes Employing p-Methoxybenzyl Chloride as +CH2-CO2 Equivalent . Tetrahedron Letters . 1988 . 29 . 52 . 6925–6926 . 10.1016/S0040-4039(00)88476-2 .
  43. House, H. O. . Crumrine, D. S. . Teranishi, A. Y. . Olmstead, H. D. . Chemistry of Carbanions. XXIII. Use of Metal Complexes to Control the Aldol Condensation . Journal of the American Chemical Society . 1973 . 95 . 10 . 3310–3324 . 10.1021/ja00791a039 .
  44. 10.1002/anie.201101380 . Magical Power of Transition Metals: Past, Present, and Future (Nobel Lecture) . 2011 . Negishi . Ei-Ichi . Angewandte Chemie International Edition . 50 . 30 . 6738–6764 . 21717531 .
  45. Chen, T.-A. . Wu, X. . Rieke, R. D. . Regiocontrolled Synthesis of Poly(3-alkylthiophenes) Mediated by Rieke Zinc: Their Characterization and Solid-State Properties. Journal of the American Chemical Society . 1995. 117. 233–244. 10.1021/ja00106a027.
  46. Rieke, R. D. . Hanson, M. V. . New Organometallic Reagents Using Highly Reactive Metals. Tetrahedron. 1997. 53. 1925–1956. 10.1016/S0040-4020(96)01097-6. 6.
  47. Book: 10.1002/14356007.a03_463.pub2 . Benzaldehyde . Ullmann's Encyclopedia of Industrial Chemistry . 2011 . Brühne . Friedrich . Wright . Elaine . 978-3-527-30385-4 .
  48. Book: ASM handbook . 1990 . American Society for Metals . ASM International . 978-0-87170-021-6 .
  49. Book: Wilson, A. D. . Nicholson, J. W. . 1993 . Acid-Base Cements: Their Biomedical and Industrial Applications . Cambridge University Press . 978-0-521-37222-0 .
  50. Book: Watts, H. . 1869 . A Dictionary of Chemistry and the Allied Branches of Other Sciences . Longmans, Green .
  51. McLean . David . Protecting wood and killing germs: 'Burnett's Liquid' and the origins of the preservative and disinfectant industries in early Victorian Britain . Business History . April 2010 . 52 . 2 . 285–305. 10.1080/00076791003610691 . 154790730 .
  52. 10.1056/nejmra1810769 . Ingestion of Caustic Substances . 2020 . Hoffman . Robert S. . Burns . Michele M. . Gosselin . Sophie . New England Journal of Medicine . 382 . 18 . 1739–1748 . 32348645 .
  53. Book: Sample, B. E. . 1997 . Methods for Field Studies of Effects of Military Smokes, Obscurants, and Riot-control Agents on Threatened and Endangered Species . DIANE Publishing . 978-1-4289-1233-5 .
  54. Book: 10.1016/C2011-0-07884-5 . Handbook on the Toxicology of Metals . 2015 . 978-0-444-59453-2. Academic Press. Gunnar F. Nordberg, Bruce A. Fowler, Monica Nordberg.
  55. Bouma . R. J. . Teuben . J. H. . Beukema . W. R. . Bansemer . R. L. . Huffman . J. C. . Caulton . K. G. . Identification of the Zinc Reduction Product of VCl3 · 3THF as [V<sub>2</sub>Cl<sub>3</sub>(THF)<sub>6</sub>]2[Zn<sub>2</sub>Cl<sub>6</sub>] | journal = Inorganic Chemistry | year = 1984 | volume = 23 | issue = 17 | pages = 2715–2718 | doi = 10.1021/ic00185a033 }} The compound contains tetrahedral and anions, so, the compound is not caesium pentachlorozincate, but caesium tetrachlorozincate chloride. No compounds containing the ion (hexachlorozincate ion) have been characterized. The compound crystallizes from a solution of in hydrochloric acid. It contains a polymeric anion with balancing monohydrated hydronium ions, ions.

    Adducts

    The adduct with thf illustrates the tendency of zinc chloride to form 1:2 adducts with weak Lewis bases. Being soluble in ethers and lacking acidic protons, this complex is used in the synthesis of organozinc compounds.[19] A related 1:2 complex is (zinc dichloride di(hydroxylamine)). Known as Crismer's salt, this complexes releases hydroxylamine upon heating.[20] The distinctive ability of aqueous solutions of to dissolve cellulose is attributed to the formation of zinc-cellulose complexes, illustrating the stability of its adducts.[21] Cellulose also dissolves in molten hydrate.[22] Overall, this behavior is consistent with Zn2+ as a hard Lewis acid.

    When solutions of zinc chloride are treated with ammonia, diverse ammine complexes are produced. In addition to the tetrahedral 1:2 complex .[23] [24] the complex also has been isolated. The latter contains the ion,. The species in aqueous solution have been investigated and show that is the main species present with also present at lower :Zn ratio.[25]

    Aqueous solutions of zinc chloride

    Zinc chloride dissolves readily in water to give species and some free chloride.[26] [27] [28] Aqueous solutions of are acidic: a 6 M aqueous solution has a pH of 1. The acidity of aqueous solutions relative to solutions of other Zn2+ salts (say the sulfate) is due to the formation of the tetrahedral chloro aqua complexes such as [ZnCl<sub>3</sub>(H<sub>2</sub>O)]-.[29] Most metal dichlorides for octahedral complexes, with stronger O-H bonds. The combination of hydrochloric acid and gives a reagent known as "Lucas reagent". Such reagents were once used a test for primary alcohols. Similar reactions are the basis of industrial routes from methanol and ethanol respectively to methyl chloride and ethyl chloride.[30]

    In alkali solution, zinc chloride converts to various zinc hydroxychlorides. These include,,, and the insoluble . The latter is the mineral simonkolleite.[31] When zinc chloride hydrates are heated, HCl gas evolves and hydroxychlorides result.[32]

    In aqueous solution, as well as other halides (bromide, iodide), behave interchangeably for the preparation of other zinc compounds. These salts giveprecipitates o zinc carbonate when treated with aqueous carbonate sources:

    Ninhydrin reacts with amino acids and amines to form a colored compound "Ruhemann's purple" (RP). Spraying with a zinc chloride solution, which is colorless, forms a 1:1 complex RP:, which is more readily detected as it fluoresces more intensely than RP.[33]

    Redox

    Anhydrous zinc chloride melts and even boils without any decomposition up to 900 °C. These unusual properties invite unusual experiments. One of the very rare examples of zinc compounds that are not Zn2+, arise by dissolving zinc metal in molten at 500–700 °C. One obtains a yellow diamagnetic solution consisting of the . The nature of this dimetallic dication has been confirmed by Raman spectroscopy. Although is unusual, mercury, a heavy congener of zinc, form a wide variety of salts, see mercurous.

    In the presence of oxygen, zinc chloride oxidizes to zinc oxide above 400 °C. Again, this observation indicates the nonoxidation of Zn2+.[34]

    Zinc hydroxychloride

    Concentrated aqueous zinc chloride dissolves zinc oxide to form zinc hydroxychloride, which is obtained as colorless crystals:[35]

    The same material forms when hydrated zinc chloride is heated.[36]

    The ability of zinc chloride to dissolve metal oxides (MO)[37] is relevant to the utility of as a flux for soldering. It dissolves passivating oxides, exposing the clean metal surface.

    Organic syntheses with zinc chloride

    Zinc chloride is an occasional laboratory reagent often as a Lewis acid. A dramatic example is the conversion of methanol into hexamethylbenzene using zinc chloride as the solvent and catalyst:[38]

    This kind of reactivity has been investigated for the valorization of C1 precursors.[39]

    Examples of zinc chloride as a Lewis acid include the Fischer indole synthesis:

    Related Lewis-acid behavior is illustrated by a traditional preparation of the dye fluorescein from phthalic anhydride and resorcinol, which involves a Friedel-Crafts acylation.[40] This transformation has in fact been accomplished using even the hydrated sample shown in the picture above. Many examples describe the use of zinc chloride in Friedel-Crafts acylation reactions.[41]

    Zinc chloride also activates benzylic and allylic halides towards substitution by weak nucleophiles such as alkenes:[42]

    In similar fashion, promotes selective reduction of tertiary, allylic or benzylic halides to the corresponding hydrocarbons.

    Zinc enolates, prepared from alkali metal enolates and, provide control of stereochemistry in aldol condensation reactions. This control is attributed to chelation at the zinc. In the example shown below, the threo product was favored over the erythro by a factor of 5:1 when .[43]

    Organozinc precursor

    Being inexpensive and anhydrous, ZnCl2 is a widely used for the synthesis of many organozinc reagents, such as those used in the palladium catalyzed Negishi coupling with aryl halides or vinyl halides. The prominence of this reaction was highlighted by the award of the 2010 Nobel Prize in Chemistry to Ei-ichi Negishi.[44]

    Rieke zinc, a highly reactive form of zinc metal, is generated by reduction of zinc dichloride with lithium. Rieke Zn is useful for the preparation of polythiophenes[45] and for the Reformatsky reaction.[46]

    Uses

    Industrial organic chemistry

    Zinc chloride is used as a catalyst or reagent in diverse reactions conducted on an industrial scale. Benzaldehyde, 20,000 tons of which is produced annually in Western countries, is produced from inexpensive toluene by exploiting the catalytic properties of zinc dichloride. This process begins with the chlorination of toluene to give benzal chloride. In the presence of a small amount of anhydrous zinc chloride, a mixture of benzal chloride are treated continuously with water according to the following stoichiometry:[47]

    Similarly zinc chloride is employed in hydrolysis of benzotrichloride, the main route to benzoyl chloride. It serves as a catalyst for the production of methylene-bis(dithiocarbamate).

    As a metallurgical flux

    The use of zinc chloride as a flux, sometimes in a mixture with ammonium chloride (see also Zinc ammonium chloride), involves the production of HCl and its subsequent reaction with surface oxides.

    Zinc chloride forms two salts with ammonium chloride: and, which decompose on heating liberating HCl, just as zinc chloride hydrate does. The action of zinc chloride/ammonium chloride fluxes, for example, in the hot-dip galvanizing process produces gas and ammonia fumes.[48]

    In textile and paper processing

    Relevant to its affinity for these materials, is used as a fireproofing agent and in fabric "refresheners" such as Febreze. Vulcanized fibre is made by soaking paper in concentrated zinc chloride.

    History

    Zinc chloride has long been known but currently practiced industrial applications all evolved in the latter half of 20th century.

    An amorphous cement formed from aqueous zinc chloride and zinc oxide was first investigated in 1855 by Stanislas Sorel. Sorel later went on to investigate the related magnesium oxychloride cement, which bears his name.[49]

    Dilute aqueous zinc chloride was used as a disinfectant under the name "Burnett's Disinfecting Fluid".[50] From 1839 Sir William Burnett promoted its use as a disinfectant as well as a wood preservative.[51] The Royal Navy conducted trials into its use as a disinfectant in the late 1840s, including during the cholera epidemic of 1849; and at the same time experiments were conducted into its preservative properties as applicable to the shipbuilding and railway industries. Burnett had some commercial success with his eponymous fluid. Following his death however, its use was largely superseded by that of carbolic acid and other proprietary products.

    Safety and health

    Zinc and chloride are essential for life. Zn2+ is a component of several enzymes, e.g., carboxypeptidase and carbonic anhydrase. Thus, aqueous solutions of zinc chlorides are rarely problematic as an acute poison. Anhydrous zinc chloride is however an aggressive Lewis acid as it can burn skin and other tissues. Ingestion of zinc chloride, often from soldering flux, requires endoscopic monitoring.[52] Another source of zinc chloride is zinc chloride smoke mixture ("HC") used in smoke grenades. Containing zinc oxide, hexachloroethane, and aluminium powder, release zinc chloride, carbon and aluminium oxide smoke, an effective smoke screen.[53] Such smoke screens can lead to fatalities.[54]

    Further reading

    • N. N. Greenwood, A. Earnshaw, Chemistry of the Elements, 2nd ed., Butterworth-Heinemann, Oxford, UK, 1997.
      • The Merck Index, 7th edition, Merck & Co, Rahway, New Jersey, USA, 1960.
    • D. Nicholls, Complexes and First-Row Transition Elements, Macmillan Press, London, 1973.
    • J. March, Advanced Organic Chemistry, 4th ed., p. 723, Wiley, New York, 1992.
    • G. J. McGarvey, in Handbook of Reagents for Organic Synthesis, Volume 1: Reagents, Auxiliaries and Catalysts for C-C Bond Formation, (R. M. Coates, S. E. Denmark, eds.), pp. 220–3, Wiley, New York, 1999.

    External links

    .