Collective excitations of dynamic Fermi surface deformations in BaFe2(As0.5P0.5)2

Abstract

We use electronic Raman scattering to study the low-energy excitations in BaFe2(As0.5P0.5)2 (Tc ≈ 16 K) samples. In addition to a superconducting pair breaking peak (2=6.7 meV) in the A1g channel with a linear tail towards zero energy, suggesting a nodal gap structure, we detect spectral features associated to Pomeranchuk oscillations in the A1g, B1g and B2g channels. We argue that the small Fermi energy of the system is an essential condition for these Pomeranchuk oscillations to be underdamped. The Pomeranchuk oscillations have the same frequencies in the B1g and B2g channels, which we explain by the mixing of these symmetries resulting from the removal of the σv and σv symmetry planes due to a large As/P disorder. Interestingly, we show that the temperature at which the peaks corresponding to the Pomeranchuk oscillations get underdamped is consistent with the non-Fermi liquid to Femi liquid crossover determined by transport, suggesting that the Pomeranchuk instability plays an important role in the low-energy physics of the Fe-based superconductors.