Spin Waves and magnetic exchange interactions in insulating Rb0.89Fe1.58Se2

Abstract

The discovery of alkaline iron selenide AFe1.6+xSe2 (A= K, Rb, Cs) superconductors has generated considerable excitement in the condensed matter physics community because superconductivity in these materials may have a different origin from the sign reversed s-wave electron pairing mechanism, a leading candidate proposed for all other Fe-based superconductors. Although AFe1.6+xSe2 are isostructural with the metallic antiferromagnetic (AF) iron pnictides such as (Ba,Ca,Sr)Fe2As2, they are insulators near x=0 and form a 5×5 blocked AF structure (Fig. 1a) completely different from the iron pnictides. If magnetism is responsible for superconductivity of all iron-based materials, it is important to determine their common magnetic features. Here we use neutron scattering to map out spin waves in the AF insulating Rb0.89Fe1.58Se2. We find that although Rb0.89Fe1.58Se2 has a N eel temperature (TN=475 K) much higher than that of the iron pnictides (TN≤ 220 K), spin waves for both classes of materials have similar zone boundary energies. A comparison of the fitted effective exchange couplings using a local moment Heisenberg Hamiltonian in Rb0.89Fe1.58Se2, (Ba,Ca,Sr)Fe2As2, and iron chalcogenide Fe1.05Te reveals that their next nearest neighbor (NNN) exchange couplings are similar. Therefore, superconductivity in all Fe-based materials may have a common magnetic origin that is intimately associated with the NNN magnetic exchange interactions, even though they have metallic or insulating ground states, different AF orders and electronic band structures.