English

Dissipative phase transition: from qubits to qudits

Quantum Physics 2024-12-16 v2

Abstract

We investigate the fate of dissipative phase transitions in quantum many-body systems when the individual constituents are qudits (dd-level systems) instead of qubits. As an example system, we employ a permutation-invariant XYXY model of NN infinite-range interacting dd-level spins undergoing individual and collective dissipation. In the mean-field limit, we identify a dissipative phase transition, whose critical point is independent of dd after a suitable rescaling of parameters. When the decay rates between all adjacent levels are identical and d4d\geq 4, the critical point expands, in terms of the ratio between dissipation and interaction strengths, to a critical region in which two phases coexist and which increases as dd grows. In addition, a larger dd leads to a more pronounced change in spin expectation values at the critical point. Numerical investigations for finite NN reveal symmetry breaking signatures in the Liouvillian spectrum at the phase transition. The phase transition is furthermore marked by maximum entanglement negativity and a significant purity change of the steady state, which become more pronounced as dd increases. Considering qudits instead of qubits thus opens new perspectives on accessing rich phase diagrams in open many-body systems.

Keywords

Cite

@article{arxiv.2405.01223,
  title  = {Dissipative phase transition: from qubits to qudits},
  author = {Lukas Pausch and François Damanet and Thierry Bastin and John Martin},
  journal= {arXiv preprint arXiv:2405.01223},
  year   = {2024}
}

Comments

21 pages, 10 figures

R2 v1 2026-06-28T16:13:54.876Z