Magnetic-field-controlled spin fluctuations and quantum criticality in Sr3Ru2O7

When the transition temperature of a continuous phase transition is tuned to absolute zero, new ordered phases and physical behaviour emerge in the vicinity of the resulting quantum critical point. Sr 3 Ru 2 O 7 can be tuned through quantum criticality with magnetic field at low temperature. Near it...

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Veröffentlicht in:	Nature communications 2021-10, Vol.12 (1), Article 5798
Hauptverfasser:	Lester, C., Ramos, S., Perry, R. S., Croft, T. P., Laver, M., Bewley, R. I., Guidi, T., Hiess, A., Wildes, A., Forgan, E. M., Hayden, S. M.
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Schlagworte:	639/766/119/2795 639/766/119/995 639/766/119/997 639/766/119/999 Absolute zero Conduction electrons Critical field (superconductivity) Critical point Electron spin Entropy Fluctuations Humanities and Social Sciences Inelastic scattering Low temperature Magnetic fields Metals multidisciplinary Neutron scattering Neutrons Phase transitions Relaxation time Science Science (multidisciplinary) Specific heat Spin density waves Thermodynamic properties Transition temperature Transition temperatures
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creator	Lester, C. Ramos, S. Perry, R. S. Croft, T. P. Laver, M. Bewley, R. I. Guidi, T. Hiess, A. Wildes, A. Forgan, E. M. Hayden, S. M.
description	When the transition temperature of a continuous phase transition is tuned to absolute zero, new ordered phases and physical behaviour emerge in the vicinity of the resulting quantum critical point. Sr 3 Ru 2 O 7 can be tuned through quantum criticality with magnetic field at low temperature. Near its critical field B c it displays the hallmark T -linear resistivity and a T log ( 1 / T ) electronic heat capacity behaviour of strange metals. However, these behaviours have not been related to any critical fluctuations. Here we use inelastic neutron scattering to reveal the presence of collective spin fluctuations whose relaxation time and strength show a nearly singular variation with magnetic field as B c is approached. The large increase in the electronic heat capacity and entropy near B c can be understood quantitatively in terms of the scattering of conduction electrons by these spin-fluctuations. On entering the spin-density-wave ordered phase present near B c , the fluctuations become stronger suggesting that the order is stabilised through an “order-by-disorder” mechanism. Sr 3 Ru 2 O 7 exhibits a quantum critical point tunable by magnetic field and has been widely used in the study of criticality. Here, by using inelastic neutron scattering, the authors measure collective magnetic excitations near the quantum critical point and relate them to thermodynamic properties and spin density wave order.
doi_str_mv	10.1038/s41467-021-26068-3
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However, these behaviours have not been related to any critical fluctuations. Here we use inelastic neutron scattering to reveal the presence of collective spin fluctuations whose relaxation time and strength show a nearly singular variation with magnetic field as B c is approached. The large increase in the electronic heat capacity and entropy near B c can be understood quantitatively in terms of the scattering of conduction electrons by these spin-fluctuations. On entering the spin-density-wave ordered phase present near B c , the fluctuations become stronger suggesting that the order is stabilised through an “order-by-disorder” mechanism. Sr 3 Ru 2 O 7 exhibits a quantum critical point tunable by magnetic field and has been widely used in the study of criticality. 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subjects	639/766/119/2795 639/766/119/995 639/766/119/997 639/766/119/999 Absolute zero Conduction electrons Critical field (superconductivity) Critical point Electron spin Entropy Fluctuations Humanities and Social Sciences Inelastic scattering Low temperature Magnetic fields Metals multidisciplinary Neutron scattering Neutrons Phase transitions Relaxation time Science Science (multidisciplinary) Specific heat Spin density waves Thermodynamic properties Transition temperature Transition temperatures
title	Magnetic-field-controlled spin fluctuations and quantum criticality in Sr3Ru2O7
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