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Enhanced quantum synchronization of a driven qubit under non-Markovian dynamics

Published 9 Nov 2023 in quant-ph | (2311.05664v2)

Abstract: Synchronizing a few-level quantum system is of fundamental importance to the understanding of synchronization in the deep quantum regime. We investigate quantum phase synchronization of a two-level system (qubit) driven by a semiclassical laser field, in the presence of a general non-Markovian dissipative environment. The phase preference of the qubit is demonstrated through Husimi Q-function, and the existence of a limit cycle is also shown in our system. Synchronization of the qubit is quantified using the shifted phase distribution. The signature of quantum phase synchronization viz the Arnold tongue is obtained from the maximal value of the shifted phase distribution. Two distinct types of qubit dynamics is considered depending on the reservoir correlation time being very short and a situation when bath correlation time is finite. In the Markov regime of the environment, the phase preference of the qubit goes away in the long time limit, whereas the long-time phase localization persists in the non-Markovian regime. We also plot the maximum of the shifted phase distribution in two ways: (a) by varying the detuning and laser driving strength, and (b) by varying the system-bath coupling and laser driving strength. Various system-environment parameters determine the synchronization regions and the qubit phase synchronization is shown to be enhanced in the non-Markov regime.

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References (23)
  1. B. Van der Pol, Lxxxviii. on “relaxation-oscillations”, The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science 2, 978 (1926).
  2. S. C. Manrubia, A. S. Mikhailov, and D. Zanette, Emergence of dynamical order: synchronization phenomena in complex systems, Vol. 2 (World Scientific, 2004).
  3. M. Rosenblum and A. Pikovsky, Synchronization: from pendulum clocks to chaotic lasers and chemical oscillators, Contemporary Physics 44, 401 (2003).
  4. T. E. Lee and H. Sadeghpour, Quantum synchronization of quantum van der pol oscillators with trapped ions, Physical Review Letters 111, 234101 (2013).
  5. S. Walter, A. Nunnenkamp, and C. Bruder, Quantum synchronization of a driven self-sustained oscillator, Physical Review Letters 112, 094102 (2014).
  6. L. B. Arosh, M. Cross, and R. Lifshitz, Quantum limit cycles and the rayleigh and van der pol oscillators, Physical Review Research 3, 013130 (2021).
  7. O. Zhirov and D. Shepelyansky, Synchronization and bistability of a qubit coupled to a driven dissipative oscillator, Physical Review Letters 100, 014101 (2008).
  8. A. Roulet and C. Bruder, Synchronizing the smallest possible system, Physical Review Letters 121, 053601 (2018a).
  9. M. Koppenhöfer and A. Roulet, Optimal synchronization deep in the quantum regime: Resource and fundamental limit, Physical Review A 99, 043804 (2019).
  10. Á. Parra-López and J. Bergli, Synchronization in two-level quantum systems, Physical Review A 101, 062104 (2020).
  11. A. Roulet and C. Bruder, Quantum synchronization and entanglement generation, Physical Review Letters 121, 063601 (2018b).
  12. L. Henriet, Environment-induced synchronization of two quantum oscillators, Physical Review A 100, 022119 (2019).
  13. G. Karpat, I. Yalçınkaya, and B. Çakmak, Quantum synchronization in a collision model, Physical Review A 100, 012133 (2019).
  14. G. Karpat, I. Yalçınkaya, and B. Çakmak, Quantum synchronization of few-body systems under collective dissipation, Physical Review A 101, 042121 (2020).
  15. M. Koppenhöfer, C. Bruder, and A. Roulet, Quantum synchronization on the ibm q system, Physical Review Research 2, 023026 (2020).
  16. I. De Vega and D. Alonso, Dynamics of non-markovian open quantum systems, Reviews of Modern Physics 89, 015001 (2017).
  17. P.-W. Chen and M. M. Ali, Investigating leggett-garg inequality for a two level system under decoherence in a non-markovian dephasing environment, Scientific Reports 4, 6165 (2014).
  18. P.-W. Chen, M. M. Ali, and S.-H. Chen, Enhanced quantum nonlocality induced by the memory of a thermal-squeezed environment, Journal of Physics A: Mathematical and Theoretical 49, 395302 (2016).
  19. M. M. Ali and P.-W. Chen, Probing nonclassicality under dissipation, Journal of Physics A: Mathematical and Theoretical 50, 435303 (2017).
  20. M. M. Ali, P.-W. Chen, and C. Radhakrishnan, Detecting quantum phase localization using arnold tongue, Physica A: Statistical Mechanics and its Applications 633, 129436 (2024).
  21. P. Haikka, T. Johnson, and S. Maniscalco, Non-markovianity of local dephasing channels and time-invariant discord, Physical Review A 87, 010103 (2013).
  22. K. Husimi, Some formal properties of the density matrix, Proceedings of the Physico-Mathematical Society of Japan. 3rd Series 22, 264 (1940).
  23. R. Gilmore, C. Bowden, and L. Narducci, Classical-quantum correspondence for multilevel systems, Physical Review A 12, 1019 (1975).

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