Enhanced superconducting transition temperature in hyper-interlayer-expanded FeSe despite the suppressed electronic nematic order and spin fluctuations

Abstract

The superconducting critical temperature, T c, of FeSe can be dramatically enhanced by intercalation of a molecular spacer layer. Here we report on a 77Se, 7Li and 1H nuclear magnetic resonance (NMR) study of the powdered hyper-interlayer-expanded Lix(C2H8N2)yFe2-zSe2 with a nearly optimal T c=45~K. The absence of any shift in the 7Li and 1H NMR spectra indicates a complete decoupling of interlayer units from the conduction electrons in FeSe layers, whereas nearly temperature-independent 7Li and 1H spin-lattice relaxation rates are consistent with the non-negligible concentration of Fe impurities present in the insulating interlayer space. On the other hand, strong temperature dependence of 77Se NMR shift and spin-lattice relaxation rate, 1/77T1, is attributed to the hole-like bands close to the Fermi energy. 1/77T1 shows no additional anisotropy that would account for the onset of electronic nematic order down to T c. Similarly, no enhancement in 1/77T1 due to the spin fluctuations could be found in the normal state. Yet, a characteristic power-law dependence 1/77T1 T4.5 still comply with the Cooper pairing mediated by spin fluctuations.