Out-of-time-ordered correlator

In quantum physics, the out-of-time-ordered correlator (OTOC) ^[1] serves as a powerful diagnostic tool for characterizing quantum chaos, information scrambling, and other aspects of many-body dynamics. In addition, it provides a quantum mechanical analog to the Lyapunov exponent, often used to characterize the sensitivity of variables to initial conditions in classical chaos. The OTOC thus provides a natural extension of classical chaos theory to the quantum realm, and can be calculated both numerically and experimentally ^[2] .

Definition

For two observable ${\displaystyle V}$ and ${\displaystyle W}$ in Heisenberg picture, the out-of-time-order correlator (OTOC) is typically defined in two different but physically closely related ways: ^{[3] [4] [5] [6] [7]}

1. Based on commutator of ${\displaystyle W(t)}$ and ${\displaystyle V(0)}$:$${\displaystyle C(t)=\langle [W(t),V(0)]^{\dagger }[W(t),V(0)]\rangle }$$direct calculation gives ${\displaystyle C(t)=\langle V(0)^{\dagger }W(t)^{\dagger }W(t)V(0)\rangle +\langle W(t)^{\dagger }V(0)^{\dagger }V(0)W(t)\rangle -\langle V(0)^{\dagger }W(t)^{\dagger }V(0)W(t)\rangle -\langle W(t)^{\dagger }V(0)^{\dagger }W(t)V(0)\rangle .}$
2. More directly $${\displaystyle F(t)=\langle W(t)^{\dagger }V(0)^{\dagger }W(t)V(0)\rangle }$$Generally ${\displaystyle C(t)=\langle V(0)^{\dagger }W(t)^{\dagger }W(t)V(0)\rangle +\langle W(t)^{\dagger }V(0)^{\dagger }V(0)W(t)\rangle -2\,\mathrm {Re} \,F(t).}$ When ${\displaystyle V}$ and ${\displaystyle W}$ are unitaries, we have ${\displaystyle C(t)=2{\big (}1-\mathrm {Re} \,F(t){\big )}.}$

where the expectation value ${\displaystyle \langle \bullet \rangle =\operatorname {Tr} [\rho \,\bullet ]}$ is usually taken over some thermal state ${\displaystyle \rho =\exp(-\beta H)/Z}$ with ${\displaystyle \beta =1/k_{B}T}$ (${\displaystyle k_{B}}$ is Boltzmann constant, ${\displaystyle T}$ is temperature) and ${\displaystyle H}$ is Hamiltonian, ${\displaystyle Z=\operatorname {Tr} \exp(-\beta H)}$ is canonical partition function.

Physically, the growth of this commutator measured by ${\displaystyle C(t)}$ tracks scrambling. And from chaos theory perspective, we have ${\displaystyle C(t)\simeq e^{\lambda _{L}t}}$ where ${\displaystyle \lambda _{L}}$ is the quantum Lyapunov exponent. This has a similar form as the classical dependence of initial pertuvation in classical chaos theory. Thus OTOC can be regarded as an indicator of quantum chaos.

See also

Quantum chaos

SYK model

Chaos theory

References

1. Larkin, A. I.; Ovchinnikov, Yu N. (1969). "Quasiclassical Method in the Theory of Superconductivity". Soviet Journal of Experimental and Theoretical Physics. 28: 1200. Bibcode:1969JETP...28.1200L.
2. Li, J., Fan, R., Wang, H., Ye, B., Zeng, B., Zhai, H., Peng, X., Du, J. (19 July 2017). "Measuring Out-of-Time-Order Correlators on a Nuclear Magnetic Resonance Quantum Simulator". Physical Review X. 7 (3). American Physical Society (APS). doi:10.1103/physrevx.7.031011.
3. Kitaev, Alexei. "Hidden correlations in the Hawking radiation and thermal noise".
4. García-Mata, Ignacio; Jalabert, Rodolfo A.; Wisniacki, Diego Ariel (2023). "Out-of-time-order correlations and quantum chaos". Scholarpedia. 18 (4) 55237. doi: 10.4249/scholarpedia.55237 . ISSN   1941-6016.
5. Shenker, Stephen H.; Stanford, Douglas (2014-03-13). "Black holes and the butterfly effect". Journal of High Energy Physics. 2014 (3): 67. arXiv: 1306.0622 . Bibcode:2014JHEP...03..067S. doi:10.1007/JHEP03(2014)067. ISSN   1029-8479.
6. Maldacena, Juan; Shenker, Stephen H.; Stanford, Douglas (2016-08-17). "A bound on chaos". Journal of High Energy Physics. 2016 (8): 106. arXiv: 1503.01409 . Bibcode:2016JHEP...08..106M. doi:10.1007/JHEP08(2016)106. ISSN   1029-8479.
7. Xu, Shenglong; Swingle, Brian (2024). "Scrambling Dynamics and Out-of-Time-Ordered Correlators in Quantum Many-Body Systems". PRX Quantum. 5 (1) 010201. arXiv: 2202.07060 . Bibcode:2024PRXQ....5a0201X. doi:10.1103/PRXQuantum.5.010201.