Anisotropic Kondo pseudo-gap in URu2Si2

Abstract

A polarized electronic Raman scattering study reveals the emergence of symmetry dependence in the electronic Raman response of single crystalline URu2Si2 below the Kondo crossover scale TK100K. In particular, the development of a coherent Kondo pseudo-gap predominantly in the Eg channel highlights strong anisotropy in the Kondo physics in URu2Si2 that has previously been neglected in theoretical models of this system. A calculation of the Raman vertices demonstrates that the strongest Raman vertex does indeed develop within the Eg channel for interband transitions and reaches a maximum along the diagonals of the Brillouin zone, implying a d-wave-like geometry for the Kondo pseudo-gap. Below the hidden order phase transition at THO= 17.5K, the magnitude of the pseudo-gap is found to be enhanced. Moreover, the anisotropy of the pseudo-gap is similar in form to that proposed for the chiral d-wave (Eg) superconducting state that appears below Tc=1.5K.