Potassium tetrachloridocuprate(II)

Synthesis and natural occurrence

The dihydrate occurs rarely in nature near volcanic vents, e.g. in Mount Vesuvius, as the mineral mitscherlichite; which is named in honor of Eilhardt Mitscherlich (1794–1863), the German crystallographer and chemist who first synthesized the compound. It was identified as pigment in some ancient artifacts.

The dihydrate can be obtained by slow evaporation of a solution of potassium chloride KCl and copper(II) chloride CuCl
2 in 2:1 molar ratio.

Crystal structure

The crystal structure of the dihydrate was partially determined in 1927 by Hendricks and Dickinson and refined in 1934 by Chrobak. The structure is tetragonal P4₂/mnm (136), Z=2, isostructural with ammonium tetrachoridocuprate(II) (NH
4)₂CuCl
4.2H
2O and rubidium tetrachoridocuprate(II) Rb
2CuCl
4.2H
2O. Each copper atom is immediately surrounded by two oxygen atoms and four chlorine atoms forming a hydrated tetrachloridocuprate(II) anion. Two of the chlorine atoms are about 0.75 angstroms further away than the other two. Each potassium atom is surrounded by four oxygen atoms, four copper atoms and eight chlorine atoms.

Synthesis

The anhydrous compound was reported in 1952 by C. M. Fontana and others. In the next two decades others reported its heat of formation and its structure.

In the mid-1970s, however, its existence was questioned. The phase diagram for the anhydrous system KCl/CuCl
2 shows KCuCl
3 as a congruently-melting compound, but not K
2CuCl
4. The dihydrate decomposes on heating above 93 °C to KCl, KCuCl
3 and water.

The doubts were put to rest when successful dehydration was achieved by T. J. Nolan an others in 1975