Kurumaji, T.
, Paul, N.
, Fang, S.
, Neves, P.
, Kang, M.
, White, J.
, Nakajima, T.
, Graf, D.
, Ye, L.
, Chan, M.
, Suzuki, T.
, Denlinger, J.
, Jozwiak, C.
, Bostwick, A.
, Rotenberg, E.
, Lynn, J.
, Kaxiras, E.
, Comin, R.
, Fu, L.
, Checkelsky, J.
and Zhao, Y.
(2025),
Electronic Commensuration of a Spin Moire Superlattice in a Layered Magnetic Semimetal, Science Advances, [online], https://doi.org/10.1126/sciadv.adu668, https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=935040
(Accessed July 9, 2025)
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Electronic Commensuration of a Spin Moire Superlattice in a Layered Magnetic Semimetal
Published
Author(s)
Takashi Kurumaji, Nisarga Paul, Shiang Fang, Paul Neves, Mingu Kang, Jonathan White, Taro Nakajima, David Graf, Linda Ye, Mun Chan, Takehito Suzuki, Jonathan Denlinger, Chris Jozwiak, Aaron Bostwick, Eli Rotenberg, , Efthimios Kaxiras, Riccardo Comin, Liang Fu, Joseph Checkelsky,
Abstract
Spin moiré superlattices (SMSs) have been proposed as a magnetic analog of crystallographic moiré systems and a source of electron minibands offering vector-field moiré tunability and Berry curvature effects. However, it has proven challenging to realize an SMS in which a large exchange coupling J is transmitted between conduction electrons and localized spins. Furthermore, most systems have carrier mean free paths lmfp shorter than their spin moiré lattice constant aspin, inhibiting miniband formation. Here, we discover that the layered magnetic semimetal EuAg4Sb2 overcomes these challenges by forming an interface with J 100 milli–electron volts transferred between a Eu triangular lattice and anionic Ag2Sb bilayers hosting a two-dimensional electron band in the ballistic regime (lmfp >> aspin). The system realizes an SMS with aspin commensurate with the Fermi momentum, leading to a marked quenching of the transport response from miniband formation. Our findings demonstrate an approach to magnetically engineering moiré superlattices and a potential route to an emergent spin-driven quantum Hall state.Citation
Science Advances
Volume
11
Issue
6
Pub Type
Journals
Download Paper
Keywords
spin moiré superlattice, neutron diffraction, ARPES, DFT calculation, magnetization, topological bands, quantum oscillations, EuAg4Sb2
Citation
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Created February 4, 2025, Updated July 9, 2025