Crystalline Cs₂KMnF₆, when prepared below 500°C, adopts a tetragonal elpasolite structure type. Differential scanning calorimetric investigations indicated that Cs₂KMnF₆ undergoes a phase transition from the low-temperature tetragonal phase (LT) to a high-temperature phase (HT) at about 530°C. Single crystals of the new HT phase could be obtained by annealing a crystalline LT specimen at 600°C followed by rapid quenching to room temperature. In the present study the structures of both phases have been studied by single-crystal X-ray diffraction techniques. The LT phase has the tetragonal space group symmetry I4/mmm, with unit-cell parameters a = 6.319(1) (a· √2 = 8.936) and c = 9.257(2) Å, and Z= 2. The HT phase has the cubic symmetry Fm3m, with the cell parameter a = 9.067 Å and Z = 4. Structural models of the LT and HT phases have been refined vs collected single-crystal X-ray reflection data to R values of 0.034 and 0.022, respectively. The uneven Mn-F bond distance distribution in the LT form, four bonds of 1.860(6) two of 2.034(9) Å, are typical for an octahedrally coordinated high-spin Mn³⁺ ion affected by Jahn-Teller effects. Due to symmetry constraints, all six octahedral Mn-F bonds in the HT form are equal to 1.931(5) Å. However, the mean square atomic displacement parameters of the fluorine atoms increases significantly from about 0.022 Ų for the LT phase to 0.042 Ų for the HT phase. The increased displacement parameters indicate that the phase transition from the LT to the HT form is associated with a directional disorder of the Jahn-Teller distortions around the Mn³⁺ ions. (C) 2000 Academic Press.