Tuning magnetism and band topology through antisite defects in Sb-doped MnBi4Te7

Chaowei Hu, Shang Wei Lien, Erxi Feng, Scott MacKey, Hung Ju Tien, Igor I. Mazin, Huibo Cao, Tay Rong Chang, Ni Ni

Research output: Contribution to journalArticlepeer-review

34 Scopus citations

Abstract

The fine control of magnetism and electronic structure in a magnetic topological insulator is crucial in order to realize various novel magnetic topological states including axion insulators, magnetic Weyl semimetals, Chern insulators, etc. Through crystal growth, transport, thermodynamic, neutron diffraction measurements, we show that under Sb doping the newly discovered intrinsic antiferromagnetic (AFM) topological insulator MnBi4Te7 evolves from AFM to ferromagnetic (FM) and then ferrimagnetic. We attribute this to the formation of Mn(Bi,Sb) antisites upon doping, which results in additional Mn sublattices that modify the delicate interlayer magnetic interactions and cause the dominant Mn sublattice to go from AFM to FM. We further investigate the effect of antisites on the band topology using the first-principles calculations. Without considering antisites, the series evolves from AFM topological insulator (x=0) to FM axion insulators. In the exaggerated case of 16.7% of periodic antisites, the band topology is modified and a type-I magnetic Weyl semimetal phase can be realized at intermediate dopings. Therefore, this doping series provides a fruitful platform with continuously tunable magnetism and topology for investigating emergent phenomena, including quantum anomalous Hall effect, Fermi arc states, etc.

Original languageEnglish
Article number054422
JournalPhysical Review B
Volume104
Issue number5
DOIs
StatePublished - Aug 1 2021

Funding

N.N. acknowledges the useful discussions with A. P. Ramirez. We thank R. Dumas at Quantum Design for measuring the isothermal magnetization up to 13 T. C.H. acknowledges the support by the Julian Schwinger Fellowship at UCLA. Work at UCLA was supported by the U.S. Department of Energy (DOE), Office of Science, Office of Basic Energy Sciences under Award No. DE-SC0021117. T.-R.C. was supported by the Young Scholar Fellowship Program from the Ministry of Science and Technology (MOST) in Taiwan, under a MOST grant for the Columbus Program, No. MOST110-2636-M-006-016, NCKU, Taiwan, and National Center for Theoretical Sciences, Taiwan. Work at NCKU was supported by the MOST, Taiwan, under Grant No. MOST107-2627-E-006-001 and Higher Education Sprout Project, Ministry of Education to the Headquarters of University Advancement at NCKU. I.M. acknowledges support from DOE under Grant No. DE-SC0021089. The work at ORNL was supported by the U.S. DOE, Office of Science, Office of Basic Energy Sciences, Early Career Research Program Award No. KC0402010, under Contract No. DE-AC05-00OR22725. This research used resources at the High Flux Isotope Reactor, the DOE Office of Science User Facility operated by ORNL.

FundersFunder number
U.S. Department of EnergyDE-AC05-00OR22725, KC0402010
Office of Science
Basic Energy SciencesDE-SC0021117
University of California, Los Angeles
National Center for Theoretical SciencesMOST107-2627-E-006-001
Ministry of EducationDE-SC0021089
Ministry of Science and Technology, TaiwanMOST110-2636-M-006-016
National Cheng Kung University Hospital

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