Your search keyword '"van Nieuwenburg, E. P. L."' showing total 4 results

1. Metal--topological-insulator transition in the quantum kicked rotator with Z2 symmetry

Author

van Nieuwenburg, E. P. L., Edge, J. M., Dahlhaus, J. P., Tworzydło, J., and Beenakker, C. W. J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The quantum kicked rotator is a periodically driven dynamical system with a metal-insulator transition. We extend the model so that it includes phase transitions between a metal and a topological insulator, in the universality class of the quantum spin Hall effect. We calculate the Z2 topological invariant using a scattering formulation that remains valid in the presence of disorder. The scaling laws at the phase transition can be studied efficiently by replacing one of the two spatial dimensions with a second incommensurate driving frequency. We find that the critical exponent does not depend on the topological invariant, in agreement with earlier independent results from the network model of the quantum spin Hall effect., Comment: 5 figures, 6 pages

Published

2012

2. Particle statistics and lossy dynamics of ultracold atoms in optical lattices

Author

Yago Malo, J., primary, van Nieuwenburg, E. P. L., additional, Fischer, M. H., additional, and Daley, A. J., additional

Published

2018

3. Metal–topological insulator transition in the quantum kicked rotator withZ2symmetry

Author

van Nieuwenburg, E. P. L., primary, Edge, J. M., additional, Dahlhaus, J. P., additional, Tworzydło, J., additional, and Beenakker, C. W. J., additional

Published

2012

4. Metal-topological insulator transition in the quantum kicked rotator with Z2 symmetry.

Author

van Nieuwenburg, E. P. L., Edge, J. M., Dahinaus, J. P., Tworzydlo, J., and Beenakker, C. W. J.

Subjects

*METAL-insulator transitions, *QUANTUM theory, *SYMMETRY (Physics), *DYNAMICAL systems, *QUANTUM Hall effect, *TOPOLOGICAL property

Abstract

The quantum kicked rotator is a periodically driven dynamical system with a metal-insulator transition. We extend the model so that it includes phase transitions between a metal and a topological insulator, in the universality class of the quantum spin Hall effect. We calculate the Z2 topological invariant using a scattering formulation that remains valid in the presence of disorder. The scaling laws at the phase transition can be studied efficiently by replacing one of the two spatial dimensions with a second incommensurate driving frequency. We find that the critical exponent does not depend on the topological invariant, in agreement with earlier independent results from the network model of the quantum spin Hall effect. [ABSTRACT FROM AUTHOR]

Published

2012