Publication details

Signatures of dephasing by mirror-symmetry breaking in weak-antilocalization magnetoresistance across the topological transition in Pb1-xSnxSe

Authors

KAZAKOV Alexander BRZEZICKI Wojciech HYART Timo TUROWSKI Bartlomiej POLACZYNSKI Jakub ADAMUS Zbigniew ALESZKIEWICZ Marta WOJCIECHOWSKI Tomasz DOMAGALA Jaroslaw Z CAHA Ondřej VARYKHALOV Andrei SPRINGHOLZ Gunther WOJTOWICZ Tomasz VOLOBUEV Valentine V DIETL Tomasz

Year of publication 2021
Type Article in Periodical
Magazine / Source Physical Review B
MU Faculty or unit

Faculty of Science

Citation
Web https://doi.org/10.1103/PhysRevB.103.245307
Doi http://dx.doi.org/10.1103/PhysRevB.103.245307
Keywords BI2SE3 THIN-FILMS; CRYSTALLINE INSULATOR; QUANTUM OSCILLATIONS; PHASE-TRANSITION; TRANSPORT; LOCALIZATION; STATES; METAL
Description Many conductors, including recently studied Dirac materials, show saturation of coherence length on decreasing temperature. This surprising phenomenon is assigned to external noise, residual magnetic impurities, or two-level systems specific to noncrystalline solids. Here, by considering the SnTe-class of compounds as an example, we show theoretically that breaking of mirror symmetry deteriorates Berry's phase quantization, leading to additional dephasing in weak-antilocalization magnetoresistance (WAL-MR). Our experimental studies of WAL-MR corroborate these theoretical expectations in (111) Pb1-xSnxSe thin film with Sn contents x corresponding to both topological crystalline insulator and topologically trivial phases. In particular, we find the shortening of the phase coherence length in samples with intentionally broken mirror symmetry. Our results indicate that the classification of quantum transport phenomena into universality classes should encompass, in addition to time-reversal and spin-rotation invariances, spatial symmetries in specific systems.

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