Thermodynamic evidence for polaron stabilization inside the antiferromagnetic order of Eu5In2Sb6

Hubert Dawczak-Dębicki; M. Victoria Ale Crivillero; Matthew S. Cook; Sean M. Thomas; Priscila F.S. Rosa; Jens Müller; Ulrich K. Rößler; Pedro Schlottmann; Steffen Wirth

doi:10.1038/s43246-024-00689-9

Thermodynamic evidence for polaron stabilization inside the antiferromagnetic order of Eu₅In₂Sb₆

Hubert Dawczak-Dębicki
, M. Victoria Ale Crivillero
, Matthew S. Cook
, Sean M. Thomas
, Priscila F.S. Rosa
, Jens Müller
, Ulrich K. Rößler
, Pedro Schlottmann
, Steffen Wirth

Correlated Electron Materials

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Materials exhibiting electronic inhomogeneities at the nanometer scale have enormous potential for applications. Magnetic polarons are one such type of inhomogeneity which link the electronic, magnetic and lattice degrees of freedom in correlated matter and often give rise to colossal magnetoresistance. Here, we investigate single crystals of Eu₅In₂Sb₆ by thermal expansion and magnetostriction along different crystallographic directions. These data provide compelling evidence for the formation of magnetic polarons in Eu₅In₂Sb₆ well above the magnetic ordering temperature. More specifically, our results are consistent with anisotropic polarons with varying extent along the different crystallographic directions. A crossover revealed within the magnetically ordered phase can be associated with a surprising stabilization of ferromagnetic polarons within the global antiferromagnetic order upon decreasing temperature. These findings make Eu₅In₂Sb₆ a rare example of such coexisting and competing magnetic orders and, importantly, shed new light on colossal magnetoresistive behavior beyond manganites.

Original language	English
Article number	248
Journal	Communications Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s43246-024-00689-9
State	Published - Dec 2024

Funding

S.W. acknowledges fruitful discussions with Oliver Stockert. Work at the Max-Planck-Institute for Chemical Physics of Solids in Dresden and at Goethe University Frankfurt was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project No. 449866704. Work at Los Alamos was performed under the auspices of the U.S. Department of Energy, Office of Basic Energy Sciences, Division of Materials Science and Engineering. M.S.C. acknowledges support from the Los Alamos Laboratory Directed Research and Development Program.

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title = "Thermodynamic evidence for polaron stabilization inside the antiferromagnetic order of Eu5In2Sb6",

abstract = "Materials exhibiting electronic inhomogeneities at the nanometer scale have enormous potential for applications. Magnetic polarons are one such type of inhomogeneity which link the electronic, magnetic and lattice degrees of freedom in correlated matter and often give rise to colossal magnetoresistance. Here, we investigate single crystals of Eu5In2Sb6 by thermal expansion and magnetostriction along different crystallographic directions. These data provide compelling evidence for the formation of magnetic polarons in Eu5In2Sb6 well above the magnetic ordering temperature. More specifically, our results are consistent with anisotropic polarons with varying extent along the different crystallographic directions. A crossover revealed within the magnetically ordered phase can be associated with a surprising stabilization of ferromagnetic polarons within the global antiferromagnetic order upon decreasing temperature. These findings make Eu5In2Sb6 a rare example of such coexisting and competing magnetic orders and, importantly, shed new light on colossal magnetoresistive behavior beyond manganites.",

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AU - Dawczak-Dębicki, Hubert

AU - Ale Crivillero, M. Victoria

AU - Cook, Matthew S.

AU - Thomas, Sean M.

AU - Rosa, Priscila F.S.

AU - Müller, Jens

AU - Rößler, Ulrich K.

AU - Schlottmann, Pedro

AU - Wirth, Steffen

PY - 2024/12

Y1 - 2024/12

N2 - Materials exhibiting electronic inhomogeneities at the nanometer scale have enormous potential for applications. Magnetic polarons are one such type of inhomogeneity which link the electronic, magnetic and lattice degrees of freedom in correlated matter and often give rise to colossal magnetoresistance. Here, we investigate single crystals of Eu5In2Sb6 by thermal expansion and magnetostriction along different crystallographic directions. These data provide compelling evidence for the formation of magnetic polarons in Eu5In2Sb6 well above the magnetic ordering temperature. More specifically, our results are consistent with anisotropic polarons with varying extent along the different crystallographic directions. A crossover revealed within the magnetically ordered phase can be associated with a surprising stabilization of ferromagnetic polarons within the global antiferromagnetic order upon decreasing temperature. These findings make Eu5In2Sb6 a rare example of such coexisting and competing magnetic orders and, importantly, shed new light on colossal magnetoresistive behavior beyond manganites.

AB - Materials exhibiting electronic inhomogeneities at the nanometer scale have enormous potential for applications. Magnetic polarons are one such type of inhomogeneity which link the electronic, magnetic and lattice degrees of freedom in correlated matter and often give rise to colossal magnetoresistance. Here, we investigate single crystals of Eu5In2Sb6 by thermal expansion and magnetostriction along different crystallographic directions. These data provide compelling evidence for the formation of magnetic polarons in Eu5In2Sb6 well above the magnetic ordering temperature. More specifically, our results are consistent with anisotropic polarons with varying extent along the different crystallographic directions. A crossover revealed within the magnetically ordered phase can be associated with a surprising stabilization of ferromagnetic polarons within the global antiferromagnetic order upon decreasing temperature. These findings make Eu5In2Sb6 a rare example of such coexisting and competing magnetic orders and, importantly, shed new light on colossal magnetoresistive behavior beyond manganites.

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Thermodynamic evidence for polaron stabilization inside the antiferromagnetic order of Eu₅In₂Sb₆

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