Giant superconducting fluctuations in the compensated semimetal FeSe at the BCS–BEC crossover

Abstract: The physics of the crossover between weak-coupling Bardeen–Cooper–Schrieffer (BCS) and strong-coupling Bose–Einstein condensate (BEC) limits gives a unified framework of quantum-bound (superfluid) states of interacting fermions. This crossover has been studied in the ultracold atomic systems, but is extremely difficult to be realized for electrons in solids. Recently, the superconducting semimetal FeSe with a transition temperature Tc=8.5 K has been found to be deep inside the BCS–BEC crossover regime. Here we… Show more

“…From (16) it follows that there is a sign change of the order parameter between hole and electron pockets. Inserting then the values of |∆ h |, |∆ e | obtained from (14), (15), into (16), we arrive at…”

“…At T = T c we can linearize the self-consistency equations (14) and (15) and obtain (assuming |µ e,h1,h2 | ≫ T c ):…”

“…Interestingly, a recent quasiparticle interference (QPI) study of FeSe 11 has revealed that the ratio of the superconducting gap to the Fermi energy on the shallow electron band is very large ∆/E Fe ∼ 1 with similar ratios ∆/E F ≈ 0.6 being reported for FeSe x Te 1−x 7,12,13 . This has been followed up by observation of strong superconducting fluctuations in FeSe far above T c [14][15][16] . The large values of ∆/E F observed initially in FeSe have been interpreted 11 as a signature of a crossover from conventional Cooper pairing (BCS) to Bose-Einstein condensation (BEC) regime 17 .…”

s+is superconductivity with incipient bands: Doping dependence and STM signatures

“…From (16) it follows that there is a sign change of the order parameter between hole and electron pockets. Inserting then the values of |∆ h |, |∆ e | obtained from (14), (15), into (16), we arrive at…”

“…At T = T c we can linearize the self-consistency equations (14) and (15) and obtain (assuming |µ e,h1,h2 | ≫ T c ):…”

“…Interestingly, a recent quasiparticle interference (QPI) study of FeSe 11 has revealed that the ratio of the superconducting gap to the Fermi energy on the shallow electron band is very large ∆/E Fe ∼ 1 with similar ratios ∆/E F ≈ 0.6 being reported for FeSe x Te 1−x 7,12,13 . This has been followed up by observation of strong superconducting fluctuations in FeSe far above T c [14][15][16] . The large values of ∆/E F observed initially in FeSe have been interpreted 11 as a signature of a crossover from conventional Cooper pairing (BCS) to Bose-Einstein condensation (BEC) regime 17 .…”

s+is superconductivity with incipient bands: Doping dependence and STM signatures

“…FeSe shows no long-range magnetic order at ambient pressure, but complex magnetic fluctuations are present at high energies over a large temperature range [9]. Below T s , the spin-lattice relaxation rate from NMR experiments is enhanced as it captures the low-energy tail of the stripe spin-fluctuations [10,11]. Furthermore, recent µSR studies invoke the close proximity of FeSe to a magnetic quantum critical point as the muon relaxation rate shows unusual temperature dependence inside the nematic state [12].The changes in the electronic structure and magnetic fluctuations of FeSe can have profound implication on its transport and superconducting properties.…”

Anomalous high-magnetic field electronic state of the nematic superconductors FeSe1−xSx

“…: the "11" compounds, have the simplest structure but a very complex electronic and magnetic behaviour [1].…”

Intrinsic pinning by naturally occurring correlated defects in FeSe_1−xTe_xsuperconductors