Valley dependent many-body effects in 2D semiconductors

Abstract

We calculate the valley degeneracy (gv) dependence of the many-body renormalization of quasiparticle properties in multivalley 2D semiconductor structures due to the Coulomb interaction between the carriers. Quite unexpectedly, the gv dependence of many-body effects is nontrivial and non-generic, and depends qualitatively on the specific Fermi liquid property under consideration. While the interacting 2D compressibility manifests monotonically increasing many-body renormalization with increasing gv, the 2D spin susceptibility exhibits an interesting non-monotonic gv dependence with the susceptibility increasing (decreasing) with gv for smaller (larger) values of gv with the renormalization effect peaking around gv 1-2. Our theoretical results provide a clear conceptual understanding of recent valley-dependent 2D susceptibility measurements in AlAs quantum wells.