Abstract
Quantum directed transport can be realized in noninteracting, deterministic, chaotic systems by appropriately breaking the spatiotemporal symmetries in the potential. In this work, the focus is on the class of interacting two-body quantum systems whose classical limit is chaotic. It is shown that one subsystem effectively acts as a source of “noise” to the other leading to intrinsic temporal symmetry breaking. Then, the quantum directed currents, even if prohibited by symmetries in the composite system, can be realized in the subsystems. This current is of quantum origin and does not arise from semiclassical effects. This protocol provides a minimal framework—broken spatial symmetry in the potential and presence of interactions—for realizing directed transport in interacting chaotic systems. It is also shown that the magnitude of directed current undergoes multiple current reversals upon varying the interaction strength and this allows for controlling the currents. It is explicitly demonstrated in the two-body interacting kicked rotor model. The interaction-induced mechanism for subsystem directed currents would be applicable to other interacting quantum systems as well.
- Received 8 July 2022
- Revised 28 March 2023
- Accepted 13 September 2023
- Corrected 1 November 2023
DOI:https://doi.org/10.1103/PhysRevE.108.044208
©2023 American Physical Society
Physics Subject Headings (PhySH)
Corrections
1 November 2023
Correction: The affiliations were erroneously changed during the proof production cycle and have been fixed. The institution that previously appeared as affiliation number 1 has been inserted in the footnote for author Sanku Paul as a current address.
