We have studied the low-energy spin-excitation spectrum of the single-crystalline Rb 2 Fe 4 Se 5 superconductor (T c = 32 K) by means of inelastic neutron scattering. In the superconducting state, we observe a magnetic resonant mode centered at an energy of hω res = 14 meV and at the (0.5 0.25 0.5) wave vector (unfolded Fe-sublattice notation), which differs from the ones characterizing magnetic resonant modes in other iron-based superconductors. Our finding suggests that the 245-iron-selenides are unconventional superconductors with a sign-changing order parameter, in which bulk superconductivity coexists with the 5 × 5 magnetic superstructure. The estimated ratios of hω res /k B T c ≈ 5.1 ± 0.4 and hω res /2∆ ≈ 0.7 ± 0.1, where ∆ is the superconducting gap, indicate moderate pairing strength in this compound, similar to that in optimally doped 1111-and 122-pnictides. PACS numbers: 74.70.Xa, 74.25.Ha, 78.70.Nx, 74.20.Rp Soon after the discovery of arsenic-free iron-selenide superconductors A 2 Fe 4 Se 5 (A = K, Rb, Cs), also known as 245-compounds [1], their unprecedented physical properties came to light, such as the coexistence of high-T c superconductivity with strong antiferromagnetism [2,3]. The pairing mechanism and the symmetry of the superconducting (SC) order parameter in this family of compounds still remain among the major open questions. In the majority of other Fe-based superconductors, it is widely accepted that the strong nesting between the holelike Fermi surface (FS) at the Brilliouin zone (BZ) center and electronlike FS at the BZ boundary leads to the sign-changing s-wave (s ± -wave) pairing symmetry [4]. This scenario has been supported by different experimental methods, such as angle-resolved photoemission spectroscopy (ARPES) [5], quasi-particle interference [6], and inelastic neutron scattering (INS) [7,8].On the other hand, recent theoretical calculations [9] and ARPES experiments [10, 11] on the 245-system revealed the absence of holelike FS at the BZ center in the electronic structure, implying that the nesting between the hole-and electronlike FS sheets is no longer present. Hence, several theoretical studies proposed alternative pairing instabilities, such as d-wave or another type of s ± -wave symmetry with sign-changing order parameter between bonding and antibonding states [12][13][14]. As a hallmark of sign-changing SC order parameter, several authors theoretically predicted a resonant mode in the magnetic excitation spectrum below the SC transition, yet its precise position in momentum space still remains controversial [12,13].A major complication in treating the 245-compounds theoretically arises from the presence of a crystallographic superstructure of Fe vacancies that has been consistently reported both from x-ray and neutron diffraction experiments [15]. This 5 × 5 superstructure is closely related to the static antiferromagnetic (AFM) order persisting up to the Néel temperature, T N ≈ 540 K [16]. Although most of the existing band structure calculations have so far negle...
