Quantum Trajectory Theory

Quantum Trajectory Theory (QTT) is a formulation of quantum mechanics used for simulating open quantum systems, quantum dissipation and single quantum systems.[1] It was developed by Howard Carmichael in the early 1990s around the same time as the similar formulation, known as the quantum jump method or Monte Carlo wave function (MCWF) method, developed by Dalibard, Castin and Mølmer.[2] Other contemporaneous works on wave-function-based Monte Carlo approaches to open quantum systems include those of Dum, Zoller and Ritsch, and Hegerfeldt and Wilser.[3]

QTT is compatible with the standard formulation of quantum theory, as described by the Schrödinger equation, but it offers a more detailed view.[4][1] The Schrödinger equation can be used to compute the probability of finding a quantum system in each of its possible states should a measurement be made. This approach is fundamentally statistical and is useful for predicting average measurements of large ensembles of quantum objects but it does not describe or provide insight into the behaviour of individual particles. QTT fills this gap by offering a way to describe the trajectories of individual quantum particles that obey the probabilities computed from the Schrödinger equation.[4][5] Like the quantum jump method, QTT applies to open quantum systems that interact with their environment.[1] QTT has become particularly popular since the technology has been developed to efficiently control and monitor individual quantum systems as it can predict how individual quantum objects such as particles will behave when they are observed.[4]

Method

In QTT open quantum systems are modelled as scattering processes, with classical external fields corresponding to the inputs and classical stochastic processes corresponding to the outputs (the fields after the measurement process).[6] The mapping from inputs to outputs is provided by a quantum stochastic process that is set up to account for a particular measurement strategy (eg., photon counting, homodyne/heterodyne detection, etc).[7] The calculated system state as a function of time is known as a quantum trajectory, and the desired density matrix as a function of time may be calculated by averaging over many simulated trajectories.

Like other Monte Carlo approaches, QTT provides an advantage over direct master-equation approaches by reducing the number of computations required. For a Hilbert space of dimension N, the traditional master equation approach would require calculation of the evolution of N2 atomic density matrix elements, whereas QTT only requires N calculations. This makes it useful for simulating large open quantum systems.[8]

The idea of monitoring outputs and building measurement records is fundamental to QTT. This focus on measurement distinguishes it from the quantum jump method which has no direct connection to monitoring output fields. When applied to direct photon detection the two theories produce equivalent results. Where the quantum jump method predicts the quantum jumps of the system as photons are emitted, QTT predicts the "clicks" of the detector as photons are measured. The only difference is the viewpoint. [8]

QTT is also broader in its application than the quantum jump method as it can be applied to many different monitoring strategies including direct photon detection and heterodyne detection. Each different monitoring strategy offers a different picture of the system dynamics.[8]

Applications

There have been two distinct phases of applications for QTT. Like the quantum jump method, QTT was first used for computer simulations of large quantum systems. These applications exploit its ability to significantly reduce the size of computations, which was especially necessary in the 1990s when computing power was very limited.[2][9][10]

The second phase of application has been catalysed by the development of technologies to precisely control and monitor single quantum systems. In this context QTT is being used to predict and guide single quantum system experiments including those contributing to the development of quantum computers.[1][11][12][13][14][15][5]

Quantum measurement problem

QTT addresses the measurement problem in quantum mechanics by providing a detailed description of what happens during the so-called "collapse of the wave function". It reconciles the concept of a quantum jump with the smooth evolution described by the Schrödinger equation. The theory suggests that "quantum jumps" are not instantaneous but happen in a coherently driven system as a smooth transition through a series of superposition states.[5] This prediction was tested experimentally in 2019 by a team at Yale University led by Michel Devoret and Zlatko Minev, in collaboration with Carmichael and others at Yale University and the University of Auckland. In their experiment they used a superconducting artificial atom to observe a quantum jump in detail, confirming that the transition is a continuous process that unfolds over time. They were also able to detect when a quantum jump was about to occur and intervene to reverse it, sending the system back to the state in which it started.[11] This experiment, inspired and guided by QTT, represents a new level of control over quantum systems and has potential applications in correcting errors in quantum computing in the future.[11][16][17][18][5][1]

Reference

  1. Ball, Phillip (28 March 2020). "Reality in the making". New Scientist: 35–38.
  2. Mølmer, K.; Castin, Y.; Dalibard, J. (1993). "Monte Carlo wave-function method in quantum optics". Journal of the Optical Society of America B. 10 (3): 524. Bibcode:1993JOSAB..10..524M. doi:10.1364/JOSAB.10.000524.
  3. The associated primary sources are, respectively:
    • Dalibard, Jean; Castin, Yvan; Mølmer, Klaus (February 1992). "Wave-function approach to dissipative processes in quantum optics". Physical Review Letters. 68 (5): 580–583. arXiv:0805.4002. Bibcode:1992PhRvL..68..580D. doi:10.1103/PhysRevLett.68.580. PMID 10045937.
    • Carmichael, Howard (1993). An Open Systems Approach to Quantum Optics. Springer-Verlag. ISBN 978-0-387-56634-4.
    • Dum, R.; Zoller, P.; Ritsch, H. (1992). "Monte Carlo simulation of the atomic master equation for spontaneous emission". Physical Review A. 45 (7): 4879–4887. Bibcode:1992PhRvA..45.4879D. doi:10.1103/PhysRevA.45.4879. PMID 9907570.
    • Hegerfeldt, G. C.; Wilser, T. S. (1992). "Ensemble or Individual System, Collapse or no Collapse: A Description of a Single Radiating Atom". In H.D. Doebner; W. Scherer; F. Schroeck, Jr. (eds.). Classical and Quantum Systems (PDF). Proceedings of the Second International Wigner Symposium. World Scientific. pp. 104–105.
  4. Ball, Philip. "The Quantum Theory That Peels Away the Mystery of Measurement". Quanta Magazine. Retrieved 2020-08-14.
  5. "Collaborating with the world's best to answer century-old mystery in quantum theory" (PDF). 2019 Dodd-Walls Centre Annual Report: 20–21.
  6. "Howard Carmichael – Physik-Schule". physik.cosmos-indirekt.de (in German). Retrieved 2020-08-14.
  7. "Dr Howard Carmichael - The University of Auckland". unidirectory.auckland.ac.nz. Retrieved 2020-08-14.
  8. "Quantum optics. Proceedings of the XXth Solvay conference on physics, Brussels, November 6–9, 1991". Physics Reports. 1991.
  9. L. Horvath and H. J. Carmichael (2007). "Effect of atomic beam alignment on photon correlation measurements in cavity QED". Physical Review A. 76, 043821 (4): 043821. arXiv:0704.1686. doi:10.1103/PhysRevA.76.043821. S2CID 56107461.
  10. R. Chrétien (2014) "Laser cooling of atoms: Monte-Carlo wavefunction simulations" Masters Thesis.
  11. Ball, Philip. "Quantum Leaps, Long Assumed to Be Instantaneous, Take Time". Quanta Magazine. Retrieved 2020-08-27.
  12. Wiseman, H. (2011). Quantum Measurement and Control. Cambridge University Press.
  13. K. W. Murch, S. J. Weber, C. Macklin, and I. Siddiqi (2014). "Observing single quantum trajectories of a superconducting quantum bit". Nature. 502 (7470): 211–214. arXiv:1305.7270. doi:10.1038/nature12539. PMID 24108052. S2CID 3648689.CS1 maint: multiple names: authors list (link)
  14. N. Roch, M. Schwartz, F. Motzoi, C. Macklin, R. Vijay, A. Eddins, A. Korotkov, K. Whaley, M. Sarovar, and I. Siddiqi (2014). "Observation of measurement-induced entanglement and quantum trajectories of remote superconducting qubits". Physical Review Letters. 112, 170501-1-4, 2014. (17): 170501. arXiv:1402.1868. doi:10.1103/PhysRevLett.112.170501. PMID 24836225. S2CID 14481406 via American Physical Society.CS1 maint: multiple names: authors list (link)
  15. P. Campagne-Ibarcq, P. Six, L. Bretheau, A. Sarlette, M. Mirrahimi, P. Rouchon, and B. Huard (2016). "Observing quantum state diffusion by heterodyne detection of fluorescence". Physical Review X. 6. doi:10.1103/PhysRevX.6.011002. S2CID 53548243.CS1 maint: multiple names: authors list (link)
  16. Shelton, Jim (3 June 2019). "Physicists can predict the jumps of Schrödinger's cat (and finally save it)". ScienceDaily. Retrieved 2020-08-25.
  17. Dumé, Isabelle (7 June 2019). "To catch a quantum jump". Physics World. Retrieved 2020-08-25.
  18. Lea, Robert (2019-06-03). "Predicting the leaps of Schrödinger's Cat". Medium. Retrieved 2020-08-25.


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