Electronic structure of FeS

Abstract: Here we report the electronic structure of FeS, a recently identified iron-based superconductor. Our high-resolution angle-resolved photoemission spectroscopy studies show two hole-like (α and β) and two electron-like (η and δ) Fermi pockets around the Brillouin zone center and corner, respectively, all of which exhibit moderate dispersion along kz. However, a third hole-like band (γ) is not observed, which is expected around the zone center from band calculations and is common in iron-based superconductors. S… Show more

“…Isoelectronic sulfur substitution in FeSe provides the most suitable route to study this issue. In the series of FeSe1−x Sx , the density of states at the Fermi level (or bandwidth) can be tuned significantly through chemical pressure, leading to a change of the electron correlation effect (34)(35)(36)(37)(38).…”

Abrupt change of the superconducting gap structure at the nematic critical point in FeSe _1−x S _x

“…Isoelectronic sulfur substitution in FeSe provides the most suitable route to study this issue. In the series of FeSe1−x Sx , the density of states at the Fermi level (or bandwidth) can be tuned significantly through chemical pressure, leading to a change of the electron correlation effect (34)(35)(36)(37)(38).…”

Abrupt change of the superconducting gap structure at the nematic critical point in FeSe _1−x S _x

“…There are two predicted cylindrical electron bands which hardly change in shape across this series, similar to the isoelectronic series BaFe 2 (As 1−x P x ) 2 [56]. The positive chemical pressure in FeSe 1−x S x results in a lattice contraction and the reduction of the c axis [41] and it would bring the Fe(Se/S) layers closer together, increasing the bandwidth and potentially leading to the suppression of the electronic correlations [29,57]. As discussed below, DFT calculations provide essential guide to understand the origin of the observed Fermi surfaces of FeSe 1−x S x , but the size are smaller, the number of hole bands is reduced compared with calculations and the k z dependence is changed.…”

“…The observed energy dispersions of FeSe 1−x S x are all renormalized and shifted, as compared to the DFT dispersions, leading to much smaller hole and electron pockets, as compared with calculations [62]. The renormalization values corresponding to the two main hole dispersions (with d xz /d xz orbital character) are around 3-4 and hardly change for any compositions inside the nematic phase toward x ∼ 0.180.18, but they are reduced to a factor of ∼1-2.3 for FeS, suggesting that the suppression of electronic correlations occurs from FeSe toward FeS [29,57]. Additionally, the highly renormalized d xy band, found at ∼50 meV below the Fermi level, remains relatively unaffected across the nematic phase transition to x ∼ 0.18 and it cannot be resolved for FeS due to the disorder effects [29].…”

“…In the end compound FeS, quantum oscillations have revealed very light effective masses ranging from 0.6-2.1 m e [67,95]. The overall trends shows that cyclotron masses are larger inside the nematic phase of FeSe 1−x S x but they are getting lighter with the increasing bandwidth [57]. The reduction of the electronic correlations toward FeS is supported by the enhanced velocities from ARPES, shown in Figure 4E [29].…”

“…With sulfur substitution, the inner hole band is shifted gradually up and it crosses the Fermi level only at the Z point from x ∼ 0.11 [40] and grows in size at x ∼ 0.18. The inner hole band does not cross the Fermi level at the Γ point for any compositions up to x ∼ 0.18; however, it has been suggested that this pocket could grow in size and become a two-dimensional cylinder for FeS ( Figures 1D,E) [29,57,67]. Interestingly, the Fermi surface of the tetragonal phase for x ∼ 0.18 is very similar to the Fermi surface of FeSe at high temperature.…”

Electronic Nematic States Tuned by Isoelectronic Substitution in Bulk FeSe1−xSx

Thin Film Studies Under Focus