Spin and orbital hybridization at specifically nested Fermi surfaces in URu2Si2

Abstract

The Fermi surface (FS) nesting properties of URu2Si2 are analyzed with particular focus on their implication for the mysterious hidden order phase. We show that there exist two Fermi surfaces that exhibit a strong nesting at the antiferromagnetic wavevector, Q0=(0,\,0,\,1). The corresponding energy dispersions fulfill the relation ε1(k)=- ε2 (k Q0) at eight FS hotspot lines. The spin-orbital characters of the involved 5f states are distinct (jz=5/2 vs. 3/2) and hence the degenerate Dirac crossings are symmetry protected in the nonmagnetic normal state. Dynamical symmetry breaking through an Ising-like spin and orbital excitation mode with jz=1 induces a hybridization of the two states, causing substantial FS gapping. Concomitant spin and orbital currents in the uranium planes give rise to a rotational symmetry breaking.