Isostructural metal-insulator transition in VO2

Lee, D[Lee, D.]; Chung, B[Chung, B.]; Shi, Y[Shi, Y.]; Kim, GY[Kim, G. -Y.]; Campbell, N[Campbell, N.]; Xue, F[Xue, F.]; Song, K[Song, K.]; Choi, SY[Choi, S. -Y.]; Podkaminer, JP[Podkaminer, J. P.]; Kim, TH[Kim, T. H.]; Ryan, PJ[Ryan, P. J.]; Kim, JW[Kim, J. -W.]; Paudel, TR[Paudel, T. R.]; Kang, JH[Kang, J. -H.]; Spinuzzi, JW[Spinuzzi, J. W.]; Tenne, DA[Tenne, D. A.]; Tsymbal, EY[Tsymbal, E. Y.]; Rzchowski, MS[Rzchowski, M. S.]; Chen, LQ[Chen, L. Q.]; Lee, J[Lee, J.]; Eom, CB[Eom, C. B.]

doi:10.1126/science.aam9189

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Cited 132 time in scopus

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Isostructural metal-insulator transition in VO2

Authors: Lee, D[Lee, D.]; Chung, B[Chung, B.]; Shi, Y[Shi, Y.]; Kim, GY[Kim, G. -Y.]; Campbell, N[Campbell, N.]; Xue, F[Xue, F.]; Song, K[Song, K.]; Choi, SY[Choi, S. -Y.]; Podkaminer, JP[Podkaminer, J. P.]; Kim, TH[Kim, T. H.]; Ryan, PJ[Ryan, P. J.]; Kim, JW[Kim, J. -W.]; Paudel, TR[Paudel, T. R.]; Kang, JH[Kang, J. -H.]; Spinuzzi, JW[Spinuzzi, J. W.]; Tenne, DA[Tenne, D. A.]; Tsymbal, EY[Tsymbal, E. Y.]; Rzchowski, MS[Rzchowski, M. S.]; Chen, LQ[Chen, L. Q.]; Lee, J[Lee, J.]; Eom, CB[Eom, C. B.]

Issue Date: 30-Nov-2018

Publisher: AMER ASSOC ADVANCEMENT SCIENCE

Citation: SCIENCE, v.362, no.6418, pp.1037 - +

Indexed: SCIE
SCOPUS

Journal Title: SCIENCE

Volume: 362

Number: 6418

Start Page: 1037

End Page: +

URI: https://scholarworks.bwise.kr/skku/handle/2021.sw.skku/16670

DOI: 10.1126/science.aam9189

ISSN: 0036-8075

Abstract: The metal-insulator transition in correlated materials is usually coupled to a symmetry-lowering structural phase transition. This coupling not only complicates the understanding of the basic mechanism of this phenomenon but also limits the speed and endurance of prospective electronic devices. We demonstrate an isostructural, purely electronically driven metal-insulator transition in epitaxial heterostructures of an archetypal correlated material, vanadium dioxide. A combination of thin-film synthesis, structural and electrical characterizations, and theoretical modeling reveals that an interface interaction suppresses the electronic correlations without changing the crystal structure in this otherwise correlated insulator. This interaction stabilizes a nonequilibrium metallic phase and leads to an isostructural metal-insulator transition. This discovery will provide insights into phase transitions of correlated materials and may aid the design of device functionalities.

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