Optical response in Weyl semimetal in model with gapped Dirac phase

Abstract

We study the optical properties of Weyl semimetal (WSM) in a model which features, in addition to the usual term describing isolated Dirac cones proportional to the Fermi velocity vF, a gap term m and a Zeeman spin-splitting term b with broken time reversal symmetry. Transport is treated within Kubo formalism and particular attention is payed to the modifications that result from a finite m and b. We consider how these modifications change when a finite residual scattering rate is included. For <m the A.C. conductivity as a function of photon energy continues to display the two quasilinear energy regions of the clean limit for below the onset of the second electronic band which is gapped at ( m+b ). For of the order m little trace of two distinct linear energy scales remain and the optical response has evolved towards that for m=b=0. Although some quantitative differences remain there are no qualitative differences. The magnitude of the D.C. conductivity σDC(T=0) at zero temperature (T=0) and chemical potential (μ=0) is altered. While it remains proportional to it becomes inversely dependent on an effective Fermi velocity out of the Weyl nodes equal to vF=vFb2-m2/b which decreases strongly as the phase boundary between Weyl semimetal and gapped Dirac phase (GDSM) is approached at b=m. The leading term in the approach to σDC(T=0) for finite T/, μ/ and / is found to be quadratic. The coefficient of these corrections tracks closely the b/m dependence of the μ=T==0 limit with differences largest near to the WSM-GDSM boundary.