Domain wall conductivity in La-doped BiFeO3

J. Seidel; P. Maksymovych; Y. Batra; A. Katan; S.Y. Yang; Qiwei He; A.P. Baddorf; S.V. Kalinin; C.H. Yang; J.-C. Yang; Y.H. Chu; E.K.H. Salje; Herbert Wormeester; M. Salmeron; R. Ramesh

doi:10.1103/PhysRevLett.105.197603

Domain wall conductivity in La-doped BiFeO3

J. Seidel, P. Maksymovych, Y. Batra, A. Katan, S.Y. Yang, Qiwei He, A.P. Baddorf, S.V. Kalinin, C.H. Yang, J.-C. Yang, Y.H. Chu, E.K.H. Salje, Herbert Wormeester, M. Salmeron, R. Ramesh

Physics of Interfaces and Nanomaterials

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Abstract

The transport physics of domain wall conductivity in La-doped bismuth ferrite (BiFeO3) has been probed using variable temperature conducting atomic force microscopy and piezoresponse force microscopy in samples with arrays of domain walls in the as-grown state. Nanoscale current measurements are investigated as a function of bias and temperature and are shown to be consistent with distinct electronic properties at the domain walls leading to changes in the observed local conductivity. Our observation is well described within a band picture of the observed electronic conduction. Finally, we demonstrate an additional degree of control of the wall conductivity through chemical doping with oxygen vacancies, thus influencing the local conductive state.

Original language	English
Article number	197603
Journal	Physical review letters
Volume	105
Issue number	19
DOIs	https://doi.org/10.1103/PhysRevLett.105.197603
Publication status	Published - 2010

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title = "Domain wall conductivity in La-doped BiFeO3",

abstract = "The transport physics of domain wall conductivity in La-doped bismuth ferrite (BiFeO3) has been probed using variable temperature conducting atomic force microscopy and piezoresponse force microscopy in samples with arrays of domain walls in the as-grown state. Nanoscale current measurements are investigated as a function of bias and temperature and are shown to be consistent with distinct electronic properties at the domain walls leading to changes in the observed local conductivity. Our observation is well described within a band picture of the observed electronic conduction. Finally, we demonstrate an additional degree of control of the wall conductivity through chemical doping with oxygen vacancies, thus influencing the local conductive state.",

author = "J. Seidel and P. Maksymovych and Y. Batra and A. Katan and S.Y. Yang and Qiwei He and A.P. Baddorf and S.V. Kalinin and C.H. Yang and J.-C. Yang and Y.H. Chu and E.K.H. Salje and Herbert Wormeester and M. Salmeron and R. Ramesh",

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T1 - Domain wall conductivity in La-doped BiFeO3

AU - Seidel, J.

AU - Maksymovych, P.

AU - Batra, Y.

AU - Katan, A.

AU - Yang, S.Y.

AU - He, Qiwei

AU - Baddorf, A.P.

AU - Kalinin, S.V.

AU - Yang, C.H.

AU - Yang, J.-C.

AU - Chu, Y.H.

AU - Salje, E.K.H.

AU - Wormeester, Herbert

AU - Salmeron, M.

AU - Ramesh, R.

PY - 2010

Y1 - 2010

N2 - The transport physics of domain wall conductivity in La-doped bismuth ferrite (BiFeO3) has been probed using variable temperature conducting atomic force microscopy and piezoresponse force microscopy in samples with arrays of domain walls in the as-grown state. Nanoscale current measurements are investigated as a function of bias and temperature and are shown to be consistent with distinct electronic properties at the domain walls leading to changes in the observed local conductivity. Our observation is well described within a band picture of the observed electronic conduction. Finally, we demonstrate an additional degree of control of the wall conductivity through chemical doping with oxygen vacancies, thus influencing the local conductive state.

AB - The transport physics of domain wall conductivity in La-doped bismuth ferrite (BiFeO3) has been probed using variable temperature conducting atomic force microscopy and piezoresponse force microscopy in samples with arrays of domain walls in the as-grown state. Nanoscale current measurements are investigated as a function of bias and temperature and are shown to be consistent with distinct electronic properties at the domain walls leading to changes in the observed local conductivity. Our observation is well described within a band picture of the observed electronic conduction. Finally, we demonstrate an additional degree of control of the wall conductivity through chemical doping with oxygen vacancies, thus influencing the local conductive state.

U2 - 10.1103/PhysRevLett.105.197603

DO - 10.1103/PhysRevLett.105.197603

M3 - Article

SN - 0031-9007

VL - 105

JO - Physical review letters

JF - Physical review letters

IS - 19

M1 - 197603

ER -

Domain wall conductivity in La-doped BiFeO3

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