Magneto-elastic interaction in cubic helimagnets with B20 structure

Abstract

The magneto-elastic interaction in cubic helimagnets with B20 symmetry is considered. It is shown that this interaction is responsible for negative contribution to the square of the spin-wave gap which is alone has to disrupt assumed helical structure. It is suggested that competition between positive part of 2I which stems from magnon-magnon interaction and its negative magneto-elastic part leads to the quantum phase transition observed at high pressure in Mn Si and Fe Ge. This transition has to occur when 2=0. For Mn Si from rough estimations at ambient pressure both parts I and |ME| are comparable with the experimentally observed gap. The magneto-elastic interaction is responsible also for 2 k modulation of the lattice where k is the helix wave-vector and contribution to the magnetic anisotropy. Experimental observation by x-ray and neutron scattering the lattice modulation allows determine the strength of anisotropic part of the magneto-elastic interaction responsible for above phenomena and the lattice helicity.