Please use this identifier to cite or link to this item: http://elar.urfu.ru/handle/10995/90337
Title: Vortex-core properties and vortex-lattice transformation in FeSe
Authors: Putilov, A. V.
Di, Giorgio, C.
Vadimov, V. L.
Trainer, D. J.
Lechner, E. M.
Curtis, J. L.
Abdel-Hafiez, M.
Volkova, O. S.
Vasiliev, A. N.
Chareev, D. A.
Karapetrov, G.
Koshelev, A. E.
Aladyshkin, A. Y.
Mel'Nikov, A. S.
Iavarone, M.
Issue Date: 2019
Publisher: American Physical Society
Citation: Vortex-core properties and vortex-lattice transformation in FeSe / A. V. Putilov, C. Di Giorgio, V. L. Vadimov, D. J. Trainer, et al. . — DOI 10.1103/PhysRevB.99.144514 // Physical Review B. — 2019. — Vol. 14. — Iss. 99. — 144514.
Abstract: Low-temperature scanning tunneling microscopy and spectroscopy has been used to image the vortex core and the vortex lattice in FeSe single crystals. The local tunneling spectra acquired at the center of elliptical vortex cores display a strong particle-hole asymmetry with spatial oscillation, characteristic of the quantum-limit vortex core. Furthermore, a quasihexagonal vortex lattice at low magnetic field undergoes noticeable rhombic distortions above a certain field ∼1.5 T. This field H∗ also reveals itself as a kink in the magnetic field dependence of the specific heat. The observation of a nearly hexagonal vortex lattice at low field is very surprising for materials with an orthorhombic crystal structure and it is in apparent contradiction with the elliptical shape of the vortex cores. These observations can be directly connected to the multiband nature of superconductivity in this material, provided we attribute them to the suppression of superconducting order parameter in one of the energy bands. Above the field H∗ the superconducting coherence length for this band can well exceed the intervortex distance which strengthens the nonlocal effects. Therefore, in addition to multiple-band effects, other possible sources that can contribute to the observed evolution of the vortex-lattice structure include nonlocal effects which cause the field-dependent interplay between the symmetry of the crystal and vortex lattice or the magnetoelastic interactions due to the strain field generated by vortices. © 2019 American Physical Society.
Keywords: CRYSTAL LATTICES
CRYSTAL SYMMETRY
IRON COMPOUNDS
IRON-BASED SUPERCONDUCTORS
MAGNETIC FIELDS
SCANNING TUNNELING MICROSCOPY
SELENIUM COMPOUNDS
SINGLE CRYSTALS
SPECIFIC HEAT
TEMPERATURE
LOW-TEMPERATURE SCANNING TUNNELING MICROSCOPY
MAGNETIC FIELD DEPENDENCES
MAGNETOELASTIC INTERACTIONS
ORTHORHOMBIC CRYSTAL STRUCTURES
PARTICLE-HOLE ASYMMETRY
SUPERCONDUCTING COHERENCE LENGTH
SUPERCONDUCTING ORDER PARAMETERS
VORTEX LATTICE STRUCTURE
VORTEX FLOW
URI: http://elar.urfu.ru/handle/10995/90337
Access: info:eu-repo/semantics/openAccess
publisher-specific, author manuscript: https://link.aps.org/licenses/aps-default-accepted-manuscript-license
SCOPUS ID: 85065188840
WOS ID: 000464720300005
PURE ID: 9315482
ISSN: 2469-9950
DOI: 10.1103/PhysRevB.99.144514
metadata.dc.description.sponsorship: Citrus Research and Development Foundation, CRDF
Government Council on Grants, Russian Federation
Russian Science Foundation, RSF: 17-12-01383, 18-72-10027
Ministero dellâ Istruzione, dellâ Università e della Ricerca, MIUR
Foundation for the Advancement of Theoretical Physics and Mathematics: 17-11-109
Ministero dellâ Istruzione, dellâ Università e della Ricerca, MIUR
Kazan Federal University
Office of Science, SC
Division of Materials Sciences and Engineering, DMSE
Russian Foundation for Basic Research, RFBR: 17-52-12044
Ministry of Education and Science of the Russian Federation, Minobrnauka
Temple University, TU
Argonne National Laboratory, ANL
Nanjing University of Science and Technology, NUST: K2-2017-084
Drexel University
The authors would like to acknowledge fruitful discussions with V. Kogan and T. Hanaguri. We also would like to acknowledge technical support during the early stage of these measurements from S. A. Moore. The work at Temple University, where low temperature scanning tunneling measurements were performed, was supported by US Department of Energy, Office of Science, Basic Energy Science, Materials Sciences and Engineering Division under Award No. DE-SC0004556. The work at Drexel University and at the M.V. Lomonosov Moscow State University was supported by the US Civilian Research and Development Foundation (CRDF Global). The work in Russia has been supported in part by the Ministry of Education and Science of the Russian Federation in the framework of the Increase Competitiveness Program of NUST MISiS Grant K2-2017-084, by Act 211 of the Government of Russian Federation, Contracts No. 02.A03.21.0004, No. 02.A03.21.0006, and No. 02.A03.21.0011 and by the Russian Government Program of Competitive Growth of Kazan Federal University. One of the authors (C.D.G.) would like to acknowledge partial support from MIUR (Ministry of Education, Universities and Research of the Italian Government). The work in IPM RAS (Nizhny Novgorod) was supported in part by the Russian Science Foundation (the calculation of the vortex-lattice characteristics Grant No. 18-72-10027; the calculation of the vortex-core deformation and the analysis of the experimental data Grant No. 17-12-01383), the Russian Foundation for Basic Research (Grant No. 17-52-12044), and Foundation for the Advancement of Theoretical Physics and Mathematics “BASIS” (Grant No. 17-11-109). The work at Argonne National Laboratory was supported by the US Department of Energy, Office of Science, Basic Energy Science, Materials Sciences and Engineering Division.
RSCF project card: 17-12-01383
18-72-10027
Appears in Collections:Научные публикации ученых УрФУ, проиндексированные в SCOPUS и WoS CC

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