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Quantum Algorithms
Generalized Hydrodynamics of Bloch Oscillations in the Absence of a Lattice
arXiv
Authors: Stefano Scopa, Philip Zechmann, Michael Knap, Jacopo De Nardis, Alvise Bastianello
Year
2026
Paper ID
63776
Status
Preprint
Abstract Read
~2 min
Abstract Words
147
Citations
N/A
Abstract
Objects subjected to a constant force generally increase their velocity over time. This expectation fails whenever their energy is a smooth and periodic function of momentum, resulting in periodic Bloch oscillations instead. Periodic dispersions, typical of lattice systems, can also emerge in continuum media through strong interactions. Here, we study the phenomenon of such Bloch oscillations in the absence of a lattice in a paradigmatic model of integrable quantum gases: the two-component Yang-Gaudin model. We derive a generalized-hydrodynamic theory of Bloch oscillations for a finite density of impurities embedded in a homogeneous interacting background, which we show to persist superimposed to a drift due to the acceleration of the center of mass. Moreover, we show the single-impurity oscillation period is renormalized at finite impurity density when two-magnon bound states are populated. Our results are relevant for ultracold atom experiments, where impurities can be created at controllable densities.
Why This Paper Matters
- It adds a 2026 reference point for readers tracking recent quantum research.
- Objects subjected to a constant force generally increase their velocity over time.
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