We investigate the quasiparticle interference (QPI) in Fe-based superconductors in both the s++-wave and s±-wave superconducting states on the basis of the five-orbital model. In the octet model for cuprate superconductors with dx2−y2-wave state, the QPI signal due to the impurity scattering at q=ki−kj (E=∣Δ(ki)∣, i=1∼8) disappears when the gap functions at ki and kj have the same sign. However, we show that this extinction rule does not hold in Fe-based superconductors with fully-gapped s-wave state. The reason is that the resonance condition E=∣Δ(ki)∣ is not satisfied under the experimental condition for Fe-based superconductors. We perform the detailed numerical study of the QPI signal using the T-matrix approximation, and show that the experimentally observed QPI peak around q2=(π,0) can be explained on the basis of both the s++-wave and s±-wave states. Furthermore, we discuss the magnetic field dependence of the QPI by considering the Zeeman effect, and find that the field-induced suppression of the peak intensity around q2 can also be explained in terms of both the s++-wave and s±-wave states.
@article{arxiv.1508.01066,
title = {Quasiparticle Interference in Fe-based Superconductors Based on a Five-Orbital Tight-Binding Model},
author = {Youichi Yamakawa and Hiroshi Kontani},
journal= {arXiv preprint arXiv:1508.01066},
year = {2015}
}