Evidence for an Fulde-Ferrell-Larkin-Ovchinnikov State with Segmented Vortices in the BCS-BEC-Crossover Superconductor FeSe

Kasahara, S.; Sato, Yuki; Licciardello, S.; Čulo, Matija; Arsenijević, Stevan; Ottenbros, Thom; Tominaga, T.; Böker, J.; Eremin, I.; Shibauchi, T.; Wosnitza, J.; Hussey, N. E.; Matsuda, Yuji

doi:10.1103/physrevlett.124.107001

Cited by 97 publications

(125 citation statements)

References 65 publications

Supporting

Mentioning

104

Contrasting

Order By: Relevance

“…Considering the largest value of the superconducting gap of bulk FeSe of Δ~2 meV 44 , the ratio 2Δ/(k B T c )~5.3 is specific to the strong coupling limit. As a result, the Pauli limiting field can reach a value determined by~Δ/ ffiffiffi g p μ B of 24.4 T for g = 2 42 , which is close to the in-plane upper critical field of bulk FeSe 47 . As the inplane critical field of FeSe thin flakes is reduced to 20 T or below one can envisage that the dominant gap Δ is reduced as well, as observed for the thicker flakes (see Fig.…”

Section: Discussionmentioning

confidence: 62%

Suppression of superconductivity and enhanced critical field anisotropy in thin flakes of FeSe

et al. 2020

View full text Add to dashboard Cite

FeSe is a unique superconductor that can be manipulated to enhance its superconductivity using different routes, while its monolayer form grown on different substrates reaches a record high temperature for a two-dimensional system. In order to understand the role played by the substrate and the reduced dimensionality on superconductivity, we examine the superconducting properties of exfoliated FeSe thin flakes by reducing the thickness from bulk down towards 9 nm. Magnetotransport measurements performed in magnetic fields up to 16 T and temperatures down to 2 K help to build up complete superconducting phase diagrams of different thickness flakes. While the thick flakes resemble the bulk behaviour, by reducing the thickness the superconductivity of FeSe flakes is suppressed. The observation of the vortex-antivortex unbinding transition in different flakes provide a direct signature of a dominant two-dimensional pairing channel. However, the upper critical field reflects the evolution of the multi-band nature of superconductivity in FeSe becoming highly two-dimensional and strongly anisotropic only in the thin limit. Our study provides detailed insights into the evolution of the superconducting properties of a multi-band superconductor FeSe in the thin limit in the absence of a dopant substrate.

show abstract

Section: Discussionmentioning

confidence: 62%

Suppression of superconductivity and enhanced critical field anisotropy in thin flakes of FeSe

et al. 2020

View full text Add to dashboard Cite

show abstract

“…The compressed air was pumped into the tube via the two holes. After the air flow was pumped into the tube, it constantly collides with the tube wall in the form of turbulence, and finally formed an air vortex in the tube, like the vortex spinning [ 18 , 19 , 20 , 21 ]. Afterwards, the air vortex continues to flow downwards, and had an effect on the jet in the electrospinning process and caused the macromolecular chains in the jet to be entangled.…”

Section: Methodsmentioning

confidence: 99%

Control of Macromolecule Chains Structure in a Nanofiber

Tian

2020

Polymers

View full text Add to dashboard Cite

Mechanical property is one of the most important properties of nanofiber membranes. Electrospinning is widely used in the preparation of nanofibers due to its advantages such as good stability and easy operation. Compared with some nature silk, the mechanical properties of nanofibers prepared by electrospinning are poor. Based on the principle of vortex spinning and DNA structure, this paper designed an air vortex electrospinning device that can control the structure of macromolecular chains in nanofibers. When a weak air vortex is generated in the electrospinning process, the macromolecule chains will entangle with each other and form a DNA-like structure so as to improve the mechanical property. In addition, when a strong air vortex is generated during the electrospinning process, the nanofibers will adhere to each other, thereby enhancing the mechanical property and enlarging the pore size.

show abstract

“…[ 30,36 ] However, in spite of its significance, universally accepted experimental evidence for the FFLO pairing has still not been obtained, although a number of experiments conducted in solid‐state systems have shown results highly suggestive of the FFLO state. [ 32,34,37–43 ] Quasi‐1D ultra‐cold fermionic systems with attractive interactions offer another promising route to its experimental demonstration.…”

Section: Unconventional Pairing Phasesmentioning

confidence: 99%

Simulating Artificial 1D Physics with Ultra‐Cold Fermionic Atoms: Three Exemplary Themes

Dobrzyniecki

Sowiński

2020

Adv Quantum Tech

View full text Add to dashboard Cite

For over twenty years, ultra‐cold atomic systems have formed an almost perfect arena for simulating different quantum many‐body phenomena and exposing their non‐obvious and very often counterintuitive features. Thanks to extremely precise controllability of different parameters they are able to capture different quantum properties which were previously recognized only as theoretical curiosities. Herein, the current experimental progress in exploring the curious 1D quantum world of fermions is traced from the perspective of three subjectively selected trends being currently under vigorous experimental validation: i) unconventional pairing in attractively interacting fermionic mixtures, ii) fermionic systems subjected to the artificial spin‐orbit coupling, iii) fermionic gases of atoms with high SU(N) symmetry of internal states.

show abstract

Evidence for an Fulde-Ferrell-Larkin-Ovchinnikov State with Segmented Vortices in the BCS-BEC-Crossover Superconductor FeSe

Cited by 97 publications

References 65 publications

Suppression of superconductivity and enhanced critical field anisotropy in thin flakes of FeSe

Suppression of superconductivity and enhanced critical field anisotropy in thin flakes of FeSe

Control of Macromolecule Chains Structure in a Nanofiber

Simulating Artificial 1D Physics with Ultra‐Cold Fermionic Atoms: Three Exemplary Themes

Contact Info

Product

Resources

About