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Superconducting FeSe studied by Mössbauer spectroscopy and magnetic measurements A. Błachowski 1 , K. Ruebenbauer 1 , J. Żukrowski 2 , J. Przewoźnik 2 , K. Wojciechowski 3 , Z.M. Stadnik 4 1 Mössbauer Spectroscopy Division, Institute of Physics, Pedagogical University , Cracow, Poland
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Superconducting FeSe studied by Mössbauer spectroscopy and magnetic measurements A. Błachowski1, K. Ruebenbauer1, J. Żukrowski2, J. Przewoźnik2, K. Wojciechowski3, Z.M. Stadnik4 1Mössbauer Spectroscopy Division, Institute of Physics, Pedagogical University, Cracow, Poland 2Solid State Physics Department, Faculty of Physics and Applied Computer Science, AGH University of Science and Technology, Cracow, Poland 3Department of Inorganic Chemistry, Faculty of Material Science and Ceramics, AGH University of Science and Technology, Cracow,Poland 4Department of Physics, University of Ottawa, Ottawa, Canada
Fe-Se phase diagram The following phases form close to the FeSe stoichiometry: 1) tetragonal P4/nmm structure similar to PbO, called β-FeSe (or α-FeSe) 2) hexagonal P63/mmc structure similar to NiAs, called δ-FeSe 3) hexagonal phase Fe7Se8 with two different kinds of order, i.e., 3c (α-Fe7Se8) or 4c (β-Fe7Se8) A tetragonal P4/nmm phase transforms into Cmma orthorhombic phase at about 90 K, and this phase is superconducting with Tc≈ 8 K.
Crystal structure of -FeSe Aim of this contribution is to answer two questions concerned with tetragonal/orthorhombic FeSe: 1) is there electron spin density (magnetic moment) on Fe ? 2) is there change of electron density on Fe nucleus during transition from P4/nmm to Cmma structure ?
Efekt Mössbauera przejście jądrowe h Spektroskopiamössbauerowska
Efekt Mössbauera - spektroskopia Ruch źródła względem absorbenta powoduje dzięki efektowi Dopplera zmianę energii kwantów V V 10 mm/s 1 mm/s 48neV hematyt Fe2O3 V
Oddziaływania nadsubtelne 1) Oddziaływanie elektryczne monopolowe elektrostatyczne monopolowe oddziaływanie ładunku jądra z ładunkiem powłok elektronowych
Oddziaływania nadsubtelne 2) Oddziaływanie elektryczne kwadrupolowe oddziaływanie momentu kwadrupolowego jądra Q z gradientem pola elektrycznego q wytwarzanym przez powłoki elektronowe
Oddziaływania nadsubtelne 3) Oddziaływanie magnetyczne dipolowe oddziaływanie dipolowego momentu magnetycznego jądra z efektywnym polem magnetycznym H w obszarze jądra
Zakład Spektroskopii Mössbauerowskiej Instytut Fizyki Uniwersytet Pedagogiczny ul. Podchorążych 2, 30-084 Kraków www.elektron.up.krakow.pl
Magnetic susceptibility measured upon cooling and subsequent warming in field of 5 Oe - point A - spin rotation in hexagonal phase - region B- magnetic anomaly correlated with transition between orthorhombic and tetragonal phases - point C- transition to the superconducting state
tetragonal phase transition orthorhombic Change in isomer shift S ↓ Change in electron density on Fe nucleus S = +0.006 mm/s ↓ ρ = –0.02 electron/a.u.3 orthorhombic orthorhombic and superconducting
tetragonal phase transition • Quadrupole splitting Δ does not change • it means that local arrangement of Seatoms around Featom does not change during phase transition orthorhombic orthorhombic orthorhombic and superconducting
Mössbauer spectra obtained in external magnetic field aligned withγ-ray beam Hyperfine magnetic field is equal to applied external magnetic field. Principal component of the electric field gradient (EFG) on Fe nucleus was found as negative.
Conclusions 1. There is no magnetic moment on iron atoms in the superconducting FeSe. 2. The electron density on iron nucleus is lowered by 0.02 electron/a.u.3 during transition from tetragonal to orthorhombic phase.