Spin-density-wave-induced anomalies in the optical conductivity of AFe2As2, (A=Ca, Sr, Ba) single-crystalline iron pnictides

Abstract

We report the complex dielectric function of high-quality AFe2As2, (A=Ca, Sr, Ba) single crystals with TN≈150\ K, 200\ K, and 138\ K, respectively, determined by broadband spectroscopic ellipsometry at temperatures 10≤ T≤300\ K and wavenumbers from 100\ cm-1 to 52000\ cm-1. In CaFe2As2 we identify the optical spin-density--wave gap 2SDW≈1250\ cm-1. The 2SDW/(kBTN) ratio, characterizing the strength of the electron-electron coupling in the spin-density--wave state, amounts to ≈12 in CaFe2As2, significantly larger than the corresponding values for the SrFe2As2 and BaFe2As2 compounds: 8.7 and 5.3, respectively. We further show that, similarly to the Ba-based compound, two characteristic SDW energy gaps can be identified in the infrared-conductivity spectra of both SrFe2As2 and CaFe2As2 and investigate their detailed temperature dependence in all three materials. This analysis reveals the existence of an anomaly in CaFe2As2 at a temperature T*≈80\ K, well below the N\'eel temperature of this compound, which implies weak coupling between the two SDW subsystems. The coupling between the two subsystems evolves to intermediate in the Sr-based and strong in the Ba-based material. The temperature dependence of the infrared phonons reveals clear anomalies at the corresponding N\'eel temperatures of the investigated compounds. In CaFe2As2, the phonons exhibit signatures of SDW fluctuations above TN and some evidence for anomalies at T*. (full abstract in PDF)