Papers
Topics
Authors
Recent
Search
2000 character limit reached

Topological extension including quantum jump

Published 8 Nov 2022 in quant-ph | (2211.04233v5)

Abstract: Non-Hermitian systems and the Lindblad form master equation have always been regarded as reliable tools in dissipative modeling. Intriguingly, existing literature often obtains an equivalent non-Hermitian Hamiltonian by neglecting the quantum jumping terms in the master equation. However, there lacks investigation into the effects of discarded terms as well as the unified connection between these two approaches. In this study, we study the Su-Schrieffer-Heeger model with collective loss and gain from a topological perspective. When the system undergoes no quantum jump events, the corresponding shape matrix exhibits the same topological properties in contrast to the traditional non-Hermitian theory. Conversely, the occurrence of quantum jumps can result in a shift in the positions of the phase transition. Our study provides a qualitative analysis of the impact of quantum jumping terms and reveals their unique role in quantum systems.

Authors (2)
Definition Search Book Streamline Icon: https://streamlinehq.com
References (68)
  1. Edge States and Topological Invariants of Non-Hermitian Systems. Physical Review Letters, 121(8):086803, 2018.
  2. Non-Hermitian Edge Burst. Physical Review Letters, 128(12):120401, 2022.
  3. Topological Bose-Mott insulators in one-dimensional non-Hermitian superlattices. Physical Review B, 102(3):035153, 2020.
  4. Non-Hermitian fractional quantum Hall states. Scientific Reports, 9(1):16895, 2019.
  5. Tony E. Lee. Anomalous edge state in a non-hermitian lattice. Phys. Rev. Lett., 116:133903, Apr 2016.
  6. Non-hermitian absorption spectroscopy. Phys. Rev. Lett., 129:093001, Aug 2022.
  7. Exceptional Topology of Non-Hermitian Systems. Reviews of Modern Physics, 93(1):015005, 2021.
  8. Dynamics of entanglement after exceptional quantum quench. Physical Review B, 103(8):085137, February 2021.
  9. Entanglement spectrum and entropy in topological non-Hermitian systems and non-unitary conformal field theories. Physical Review Research, 2(3):033069, July 2020.
  10. Biorthogonal Bulk-Boundary Correspondence in Non-Hermitian Systems. Physical Review Letters, 121(2):026808, 2018.
  11. Volume-to-area law entanglement transition in a non-Hermitian free fermionic chain. SciPost Physics, 14(5):138, May 2023.
  12. Simon Lieu. Topological phases in the non-Hermitian Su-Schrieffer-Heeger model. Physical Review B, 97(4):045106, January 2018.
  13. Dissipative Topological Phase Transition with Strong System-Environment Coupling. Physical Review Letters, 127(25):250402, 2021.
  14. Unraveling the topology of dissipative quantum systems. Physical Review Research, 4(2):023036, 2022.
  15. Topology by dissipation. New Journal of Physics, 15(8):085001, 2013.
  16. Topological invariants in dissipative extensions of the Su-Schrieffer-Heeger model. Physical Review A, 98(1):013628, 2018.
  17. The Theory of Open Quantum Systems. Oxford University Press, 2002.
  18. Quantum noise: a handbook of Markovian and non-Markovian quantum stochastic methods with applications to quantum optics. Springer Science & Business Media, 2004.
  19. Quantum exceptional points of non-Hermitian Hamiltonians and Liouvillians: The effects of quantum jumps. Physical Review A, 100(6):062131, 2019.
  20. Theory of Non-Hermitian Fermionic Superfluidity with a Complex-Valued Interaction. Physical Review Letters, 123(12):123601, 2019.
  21. Effect of quantum jumps on non-Hermitian systems. Physical Review A, 108(3):032214, September 2023.
  22. Andrew J. Daley. Quantum trajectories and open many-body quantum systems. Advances in Physics, 63(2):77–149, 2014.
  23. Juan Mauricio Torres. Closed-form solution of Lindblad master equations without gain. Physical Review A, 89(5):052133, 2014.
  24. Non-Hermitian physics. Advances in Physics, 69(3):249–435.
  25. Non-Hermitian skin effect and chiral damping in open quantum systems. Physical Review Letters, 123(17):170401, 2019.
  26. Stefano Longhi. Unraveling the non-Hermitian skin effect in dissipative systems. Physical Review B, 102(20):201103, 2020.
  27. Fate of fractional quantum Hall states in open quantum systems: Characterization of correlated topological states for the full Liouvillian. Physical Review Research, 2(3):033428, 2020.
  28. Topological Phases of Non-Hermitian Systems. Physical Review X, 8(3):031079, 2018.
  29. Topological phases protected by shifted sublattice symmetry in dissipative quantum systems. Physical Review B, 106(3):035408, 2022.
  30. Nonequilibrium stationary states of quantum non-Hermitian lattice models. Physical Review B, 105(6):064302, 2022.
  31. Liouvillian skin effect in an exactly solvable model. Physical Review Research, 4(2):023160, 2022.
  32. Monte Carlo wave-function method in quantum optics. Journal of the Optical Society of America B, 10(3):524, 1993.
  33. Hybrid-Liouvillian formalism connecting exceptional points of non-Hermitian Hamiltonians and Liouvillians via postselection of quantum trajectories. Physical Review A, 101(6):062112.
  34. Lieb-liniger model of a dissipation-induced tonks-girardeau gas. Physical Review A, 79(2):023614, 2009.
  35. Quantum critical behavior influenced by measurement backaction in ultracold gases. Physical Review A, 94(5):053615, 2016.
  36. Zeno Hall Effect. Physical Review Letters, 118(20):200401.
  37. Tomaž Prosen. Third quantization: A general method to solve master equations for quadratic open Fermi systems. New Journal of Physics, 10(4):043026, 2008.
  38. Quantization over boson operator spaces. Journal of Physics A: Mathematical and Theoretical, 43(39):392004.
  39. Nonequilibrium perturbation theory in Liouville-Fock space for inelastic electron transport. Journal of Physics: Condensed Matter, 24(22):225304, 2012.
  40. Manfred Schmutz. Real-time green’s functions in many body problems. Zeitschrift für Physik B Condensed Matter, 30(1):97–106, 1978.
  41. Comparison and unification of non-Hermitian and Lindblad approaches with applications to open quantum optical systems. Journal of Modern Optics, 61(16):1298–1308, 2014.
  42. Nonstandard symmetry classes in mesoscopic normal-superconducting hybrid structures. Physical Review B, 55(2):1142–1161, 1997.
  43. Alexei Kitaev. Periodic table for topological insulators and superconductors. In AIP conference proceedings, volume 1134, pages 22–30. American Institute of Physics, 2009.
  44. Topological insulators and superconductors: Tenfold way and dimensional hierarchy. New Journal of Physics, 12(6):065010, 2010.
  45. Symmetry and Topology in Non-Hermitian Physics. Physical Review X, 9(4):041015, October 2019.
  46. Tenfold Way for Quadratic Lindbladians. Physical Review Letters, 124(4):040401, 2020.
  47. Topological classifications of quadratic bosonic excitations in closed and open systems with examples. Journal of Physics: Condensed Matter, 34(17):175403, feb 2022.
  48. Defective edge states and number-anomalous bulk-boundary correspondence in non-Hermitian topological systems. Physical Review B, 101(12):121116, 2020.
  49. Geometrical meaning of winding number and its characterization of topological phases in one-dimensional chiral non-Hermitian systems. Physical Review A, 97(5):052115, 2018.
  50. Ye Xiong. Why does bulk boundary correspondence fail in some non-hermitian topological models. Journal of Physics Communications, 2(3):035043, mar 2018.
  51. Non-Bloch Band Theory of Non-Hermitian Systems. Physical Review Letters, 123(6):066404, 2019.
  52. Non-hermitian chern bands. Physical review letters, 121(13):136802, 2018.
  53. Topological Origin of Non-Hermitian Skin Effects. Physical Review Letters, 124(8):086801, February 2020.
  54. Non-Bloch band theory of non-Hermitian Hamiltonians in the symplectic class. Physical Review B, 101(19):195147, 2020.
  55. Connections between the open-boundary spectrum and the generalized Brillouin zone in non-Hermitian systems. Physical Review B, 105(4):045422, 2022.
  56. Correspondence between winding numbers and skin modes in non-hermitian systems. Physical Review Letters, 125(12):126402, 2020.
  57. Non-Hermitian bulk-boundary correspondence and singular behaviors of generalized Brillouin zone. New Journal of Physics, 23(12):123007, 2021.
  58. Non-Hermitian Bulk-Boundary Correspondence and Auxiliary Generalized Brillouin Zone Theory. Physical Review Letters, 125(22):226402, 2020.
  59. Density-matrix chern insulators: Finite-temperature generalization of topological insulators. Phys. Rev. B, 88:155141, Oct 2013.
  60. Dynamical signatures of topological order in the driven-dissipative Kitaev chain. SciPost Physics, 6(2):026, February 2019.
  61. Classification of topological quantum matter with symmetries. Reviews of Modern Physics, 88(3):035005, 2016.
  62. New topological invariants in non-Hermitian systems. Journal of Physics: Condensed Matter, 31(26):263001, 2019.
  63. Ebook: Complex Variables and Applications. McGraw Hill, 2014.
  64. J. Zak. Berry’s phase for energy bands in solids. Physical Review Letters, 62(23):2747–2750, 1989.
  65. Complex geometrical phases for dissipative systems. Physics Letters A, 128(3-4):177–181, 1988.
  66. Yasuhiro Hatsugai. Quantized Berry Phases as a Local Order Parameter of a Quantum Liquid. Journal of the Physical Society of Japan, 75(12):123601, 2006.
  67. Exact diagonalization: The Bose–Hubbard model as an example. European Journal of Physics, 31(3):591–602, May 2010.
  68. Léon Van Hove. The occurrence of singularities in the elastic frequency distribution of a crystal. Phys. Rev., 89:1189–1193, Mar 1953.
Citations (2)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 1 tweet with 0 likes about this paper.

Sign Up for Free