Raman signature of the U(1) Dirac spin-liquid state in spin-1/2 kagome system

Abstract

We followed the Shastry--Shraiman formulation of Raman scattering in Hubbard systems and considered the Raman intensity profile in the spin-1/2 "perfect" kagome lattice herbertsmithite ZnCu3(OH)6Cl2, assuming the ground state is well-described by the U(1) Dirac spin-liquid state. In the derivation of the Raman T-matrix, we found that the spin chirality term appears in the A2g channel in the kagome lattice at the t4/(ωi-U)3 order, but (contrary to the claims by Shastry and Shraiman) vanishes in the square lattice to that order. In the ensuing calculations on the spin-1/2 kagome lattice, we found that the Raman intensity profile in the Eg channel is invariant under an arbitrary rotation in the kagome plane, and that in all (A1g, Eg, and A2g) symmetry channels the Raman intensity profile contains broad continua that display power-law behaviors at low energy, with exponent approximately equal to 1 in the A2g channel and exponent approximately equal to 3 in the Eg and the A1g channels. For the A2g channel, the Raman profile also contains a characteristic 1/ω singularity, which arose in our model from an excitation of the emergent U(1) gauge field.