Orbital magnetism in an electric field-driven Mott insulator
ORAL
Abstract
Motivated by the recent discovery of electric field-induced strong diamagnetism
in a Mott insulator Ca2RuO4 [1], we use the gauge invariant Keldysh Green function
formalism to investigate the roles of electric field in the orbital magnetism of a two-band
Mott insulator. We first generalize the Landau-Peierls formula for orbital susceptibility to
account for both inter-band and nonequilibrium effects. We find that the electric field
induces an over-population of hot electrons due to Joule heating and reduces the band gap.
This drives the system closer to a semimetallic state with light mass conduction electrons,
and leads to an enhancement of diamagnetism.
[1] C. Sow, S. Yonezawa, S. Kitamura, T. Oka, K. Kuroki, F. Nakamura, and Y. Maeno,
Science 358, 1084 (2017).
in a Mott insulator Ca2RuO4 [1], we use the gauge invariant Keldysh Green function
formalism to investigate the roles of electric field in the orbital magnetism of a two-band
Mott insulator. We first generalize the Landau-Peierls formula for orbital susceptibility to
account for both inter-band and nonequilibrium effects. We find that the electric field
induces an over-population of hot electrons due to Joule heating and reduces the band gap.
This drives the system closer to a semimetallic state with light mass conduction electrons,
and leads to an enhancement of diamagnetism.
[1] C. Sow, S. Yonezawa, S. Kitamura, T. Oka, K. Kuroki, F. Nakamura, and Y. Maeno,
Science 358, 1084 (2017).
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Presenters
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Subrata Chakraborty
Queens College CUNY
Authors
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Subrata Chakraborty
Queens College CUNY
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So Takei
Queens College CUNY, Queens College, The Graduate Center, City University of New York