Ballistic-to-diffusive transition in spin chains with broken integrability
ORAL
Abstract
We study the ballistic-to-diffusive transition induced by the weak breaking of integrability in a boundary-driven XXZ spin-chain. Studying the evolution of the spin current density Js as a function of the system size L, we show that, accounting for boundary effects, the transition has a non-trivial universal behavior close to the XX limit. It is controlled by the scattering length L*~ V-2, where V is the strength of the integrability breaking term.
In the XXZ model, the interplay of interactions controls the emergence of a transient ``quasi-ballistic'' regime at length scales much shorter than L*.
This parametrically large regime is characterized by a strong renormalization of the current which forbids a universal scaling, unlike the XX model.
Our results are based on Matrix Product Operator numerical simulations and agree with perturbative analytical calculations.
In the XXZ model, the interplay of interactions controls the emergence of a transient ``quasi-ballistic'' regime at length scales much shorter than L*.
This parametrically large regime is characterized by a strong renormalization of the current which forbids a universal scaling, unlike the XX model.
Our results are based on Matrix Product Operator numerical simulations and agree with perturbative analytical calculations.
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Presenters
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João Ferreira
Univ of Geneva
Authors
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João Ferreira
Univ of Geneva
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Michele Filippone
Univ of Geneva