Vortex dynamics and Hall conductivity of hard-core bosons
Abstract
Magnetotransport of hard-core bosons is studied using an XXZ quantum spin model representation, appropriately gauged on the torus to allow for an external magnetic field. We find strong lattice effects near half filling. An effective quantum mechanical description of the vortex degrees of freedom is derived. Using semiclassical and numerical analysis we compute the vortex-hopping energy t_V, which at half filling is close to magnitude of the boson hopping energy. The critical quantum melting density of the vortex lattice is estimated at 6.5×10^(−3) vortices per unit cell. The Hall conductance is computed from the Chern numbers of the low-energy eigenstates. At zero temperature, it reverses sign abruptly at half filling. At precisely half filling, all eigenstates are doubly degenerate for any odd number of flux quanta. We prove the exact degeneracies on the torus by constructing an SU(2) algebra of point-group symmetries, associated with the center of vorticity. This result is interpreted as if each vortex carries an internal spin-half degree of freedom, which can manifest itself as a charge density modulation in its core. Our findings suggest interesting experimental implications for vortex motion of cold atoms in optical lattices and magnet transport of short coherence length superconductors.
Additional Information
© 2010 The American Physical Society. Received 9 June 2010; revised manuscript received 22 July 2010; published 7 October 2010. We thank Ehud Altman, Yosi Avron, David Ceperley, Misha Feigelman, Steve Kivelson, Gil Refael, and Ady Stern for useful discussions. Support of the U.S. Israel Binational Science Foundation and Israel Science Foundation are gratefully acknowledged. A.A. and D.P.A. acknowledge Aspen Center For Physics where many of the ideas were conceived. N.L. acknowledges the financial support of the Israel Clore foundation.Attached Files
Published - Lindner2010p11632Phys_Rev_B.pdf
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Additional details
- Eprint ID
- 20535
- Resolver ID
- CaltechAUTHORS:20101026-101338340
- U.S. Israel Binational Science Foundation
- Israel Science Foundation
- Israel Clore foundation
- Created
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2010-11-19Created from EPrint's datestamp field
- Updated
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2021-11-09Created from EPrint's last_modified field