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Main Authors: Fields, Shelby S., Prestigiacomo, Joseph C., Cress, Cory D., Combs, Nicholas G., Erve, Olaf van 't, Callahan, Patrick G., Knipling, Keith E., Jamer, Michelle E., Abel, Frank M., Ye, Feng, Minelli, Arianna, Morgan, Zachary J., Ambaye, Haile, Matsuda, Masaaki, Maity, Avishek, Lauter, Valeria, Bennett, Steven P.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.22866
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author Fields, Shelby S.
Prestigiacomo, Joseph C.
Cress, Cory D.
Combs, Nicholas G.
Erve, Olaf van 't
Callahan, Patrick G.
Knipling, Keith E.
Jamer, Michelle E.
Abel, Frank M.
Ye, Feng
Minelli, Arianna
Morgan, Zachary J.
Ambaye, Haile
Matsuda, Masaaki
Maity, Avishek
Lauter, Valeria
Bennett, Steven P.
author_facet Fields, Shelby S.
Prestigiacomo, Joseph C.
Cress, Cory D.
Combs, Nicholas G.
Erve, Olaf van 't
Callahan, Patrick G.
Knipling, Keith E.
Jamer, Michelle E.
Abel, Frank M.
Ye, Feng
Minelli, Arianna
Morgan, Zachary J.
Ambaye, Haile
Matsuda, Masaaki
Maity, Avishek
Lauter, Valeria
Bennett, Steven P.
contents Initially identified as a promising altermagnetic (AM) candidate, rutile RuO$_2$ has since become embroiled in controversy due to contradictory findings of modeling and measurements of the magnetic properties of bulk crystals and thin films. For example, despite observations of a bulk non-magnetic state using density functional theory, neutron scattering, and muon spin resonance measurements, patterned RuO$_2$ Hall bars and film heterostructures display magnetotransport signatures of magnetic ordering. Among the characteristics routinely cited as evidence for AM is the observation of exchange bias (EB) in an intimately contacted Fe-based ferromagnetic (FM) layer, which can arise due to interfacial coupling with a compensated antiferromagnet. Within this work, the origins of this EB coupling in Ru-capped RuO$_2$/Fe bilayers are investigated using polarized neutron diffraction, polarized neutron reflectometry, cross-sectional transmission electron microscopy, and super conducting quantum interference device measurements. These experiments reveal that the EB behavior is driven by the formation of an iron oxide interlayer containing Fe$_3$O$_4$ that undergoes a magnetic transition and pins interfacial moments within Fe at low temperature. These findings are confirmed by comparable measurements of Ni-based heterostructures, which do not display EB coupling, as well as magnetometry of additional Fe/Ru bilayers that display oxide-driven EB coupling despite the absence of the epitaxial RuO$_2$ layer. While these results do not directly refute the possibility of AM ordering in RuO$_2$ thin films, they reveal that EB, and related magnetotransport phenomena, cannot alone be considered evidence of this characteristic in the rutile structure due to interfacial chemical disorder.
format Preprint
id arxiv_https___arxiv_org_abs_2509_22866
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Non-Altermagnetic Origin of Exchange Bias Behaviors in Incoherent RuO$_2$/Fe Bilayer Heterostructures
Fields, Shelby S.
Prestigiacomo, Joseph C.
Cress, Cory D.
Combs, Nicholas G.
Erve, Olaf van 't
Callahan, Patrick G.
Knipling, Keith E.
Jamer, Michelle E.
Abel, Frank M.
Ye, Feng
Minelli, Arianna
Morgan, Zachary J.
Ambaye, Haile
Matsuda, Masaaki
Maity, Avishek
Lauter, Valeria
Bennett, Steven P.
Materials Science
Initially identified as a promising altermagnetic (AM) candidate, rutile RuO$_2$ has since become embroiled in controversy due to contradictory findings of modeling and measurements of the magnetic properties of bulk crystals and thin films. For example, despite observations of a bulk non-magnetic state using density functional theory, neutron scattering, and muon spin resonance measurements, patterned RuO$_2$ Hall bars and film heterostructures display magnetotransport signatures of magnetic ordering. Among the characteristics routinely cited as evidence for AM is the observation of exchange bias (EB) in an intimately contacted Fe-based ferromagnetic (FM) layer, which can arise due to interfacial coupling with a compensated antiferromagnet. Within this work, the origins of this EB coupling in Ru-capped RuO$_2$/Fe bilayers are investigated using polarized neutron diffraction, polarized neutron reflectometry, cross-sectional transmission electron microscopy, and super conducting quantum interference device measurements. These experiments reveal that the EB behavior is driven by the formation of an iron oxide interlayer containing Fe$_3$O$_4$ that undergoes a magnetic transition and pins interfacial moments within Fe at low temperature. These findings are confirmed by comparable measurements of Ni-based heterostructures, which do not display EB coupling, as well as magnetometry of additional Fe/Ru bilayers that display oxide-driven EB coupling despite the absence of the epitaxial RuO$_2$ layer. While these results do not directly refute the possibility of AM ordering in RuO$_2$ thin films, they reveal that EB, and related magnetotransport phenomena, cannot alone be considered evidence of this characteristic in the rutile structure due to interfacial chemical disorder.
title Non-Altermagnetic Origin of Exchange Bias Behaviors in Incoherent RuO$_2$/Fe Bilayer Heterostructures
topic Materials Science
url https://arxiv.org/abs/2509.22866