Effect of Pt vacancies on magnetotransport of Weyl semimetal candidate GdPtSb epitaxial films

Dongxue Du, Laxman Raju Thoutam, Konrad T. Genser, Chenyu Zhang, Karin M. Rabe, Tamalika Samanta, Taehwan Jung, Bharat Jalan, Paul M. Voyles, Jason K. Kawasaki

Research output: Contribution to journalArticlepeer-review

Abstract

We examine the effects of Pt vacancies on the magnetotransport properties of Weyl semimetal candidate GdPtSb films, grown by molecular beam epitaxy on c-plane sapphire. Rutherford backscattering spectrometry and x-ray diffraction measurements suggest that phase-pure GdPtxSb films can accommodate up to 15% of Pt vacancies (x=0.85), which act as acceptors, as measured by the Hall effect. Two classes of electrical transport behavior are observed. Pt-deficient films display metallic temperature-dependent resistivity (dρ/dT>0). The longitudinal magnetoresistance (LMR, magnetic field B parallel to electric field E) is more negative than transverse magnetoresistance (TMR, B⊥E), consistent with the expected chiral anomaly for a Weyl semimetal. The combination of Pt-vacancy disorder and doping away from the expected Weyl nodes, however, suggests that conductivity fluctuations may explain the negative LMR rather than chiral anomaly. Samples closer to stoichiometry display the opposite behavior: semiconductorlike resistivity (dρ/dT>0) and more negative TMR than LMR. Hysteresis and other nonlinearities in the low-field Hall effect and magnetoresistance suggest that spin-disorder scattering and possible topological Hall effect may dominate the near-stoichiometric samples. Our findings highlight the complications of transport-based identification of Weyl nodes but point to possible topological spin textures in GdPtSb.

Original languageEnglish (US)
Article number084204
JournalPhysical Review Materials
Volume7
Issue number8
DOIs
StatePublished - Aug 2023

Bibliographical note

Funding Information:
We thank Max Hirschberger for helpful discussions on chiral anomaly tests. We thank Greg Haugstad for performing RBS measurements. Special thanks to D. R. Hamman for providing the Gd pseudopotential. Heusler epitaxial film growth and magnetotransport at the University of Wisconsin were supported by the Air Force Office of Scientific Research (No. FA9550-21-0127). Preliminary synthesis was supported by the Army Research Office (Award No. W911NF-17-1-0254) and the National Science Foundation (NSF, No. DMR-1752797). Calculations by K.R. and K.G. were supported by the Office of Naval Research No. N00014-21-1-2107. Transport measurements at the University of Minnesota by L.R.T. and B.J. were supported by the NSF through the University of Minnesota Materials Research Science and Engineering Center (MRSEC) under Award No. DMR-2011401. TEM experiments by C.Z. and P.M.V. were supported by the U.S. Department of Energy, Basic Energy Sciences (No. DE-FG02-08ER46547), and used facilities are supported by the Wisconsin MRSEC (No. DMR-1720415). We gratefully acknowledge the use of XRD facilities supported by the NSF through the University of Wisconsin MRSEC under Grant No. DMR-1720415. Sapphire substrate annealing was supported by the National Science Foundation Platform for the Accelerated Realization, Analysis, and Discovery of Interface Materials (PARADIM) under Cooperative Agreement No. DMR-2039380.

Publisher Copyright:
© 2023 American Physical Society.

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