Adiabatic nonlinear probes of one-dimensional Bose gases

We discuss two complementary problems: adiabatic loading of one-dimensional bosons into an optical lattice and merging two one-dimensional Bose systems. Both problems can be mapped to the sine-Gordon model. This mapping allows us to find power-law scalings for the number of excitations with the ramp...

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Veröffentlicht in:	arXiv.org 2008-12
Hauptverfasser:	De Grandi, C, Barankov, R A, Polkovnikov, A
Format:	Artikel
Sprache:	eng
Schlagworte:	Adiabatic flow Bosons Legal issues Mapping Nonlinear response Optical lattices Physics - Other Condensed Matter Power law
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description	We discuss two complementary problems: adiabatic loading of one-dimensional bosons into an optical lattice and merging two one-dimensional Bose systems. Both problems can be mapped to the sine-Gordon model. This mapping allows us to find power-law scalings for the number of excitations with the ramping rate in the regime where the conventional linear response approach fails. We show that the exponent of this power law is sensitive to the interaction strength. In particular, the response is larger, or less adiabatic, for strongly (weakly) interacting bosons for the loading (merging) problem. Our results illustrate that in general the nonlinear response to slow relevant perturbations can be a powerful tool for characterizing properties of interacting systems.
doi_str_mv	10.48550/arxiv.0804.4003
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subjects	Adiabatic flow Bosons Legal issues Mapping Nonlinear response Optical lattices Physics - Other Condensed Matter Power law
title	Adiabatic nonlinear probes of one-dimensional Bose gases
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