Topological phase transition induced by random substitution

Abstract

The transition from topologically nontrivial to a trivial state is studied by first-principles calculations on bulk zinc-blende type (Hg1-xZnx)(Te1-xSx) disordered alloy series. The random chemical disorder was treated by means of the Coherent Potential Approximation. We found that although the phase transition occurs at the strongest disorder regime (x≈ 0.5), it is still manifested by well-defined Bloch states forming a clear Dirac cone at the Fermi energy of the bulk disordered material. The computed residual resistivity tensor confirm the topologically-nontrivial state of the HgTe-rich (x<0.5), and the trivial state of the ZnS-rich alloy series (x>0.5) by exhibiting the quantized behavior of the off-diagonal spin-projected component, independently on the concentration x.