Is orbital ordering in crystals a magnetic phase transition?

It is shown that the time-reversal symmetry is broken during the phase transition causing orbital ordering in a crystal with Jahn-Teller (J-T) ions. This means that such phase transitions are magnetic ones. As an example we have considered the spinel crystals containing $T_{2g}$ ions: $NiCr_2O_4$ ($T_{orb}=310$ K, $T_c=70$ K) and $CuCr_2O_4$ ($T_{orb}=860$ K, $T_c=135$ K), where the orbital ordering precedes the spin ordering, which occurs at lower temperatures. The spin-ordering transition is naturally included into our general group-theoretical scheme of the phase transition. Based on the symmetry group of the parent phase, the symmetry groups for possible orbital- and spin-ordered phases are found. We present arguments in favor of the idea that the orbital ordering occurs due to the superexchange between J-T ions, and the spin ordering is caused by the spin-orbital interaction. At the same time, the displacements of atoms of the coordination polyhedron do not lead to the removal of the orbital degeneracy, and they are merely an accompanying effect.
Comment: 22 pages, in English language, 2 figures