- Department of Nanoengineering, Kyonggi University, Suwon, Korea
The investigation of quantum–classical correspondence may lead to gaining a deeper understanding of the classical limit of quantum theory. I have developed a quantum formalism on the basis of a linear invariant theorem, which gives an exact quantum–classical correspondence for damped oscillatory systems perturbed by an arbitrary force. Within my formalism, the quantum trajectory and expectation values of quantum observables precisely coincide with their classical counterparts in the case where the global quantum constant
1 Introduction
A fundamental issue in physics is to elucidate how classical mechanics (or Newtonian mechanics) emerges from a more general theory of physics, the so-called relativistic quantum mechanics. While the appearing of classical mechanics as a low velocity limit of relativistic mechanics is well known, the classical limit of quantum mechanics is a subtle problem yet. Planck’s
The purpose of this research is to establish a theoretical formalism concerning the classical limit of quantum mechanics for damped driven oscillatory systems, which reveals the quantum and classical correspondence, without any approximation or assumption except for the fundamental limitation
2 Invariant-Based Dynamics and Quantum Solutions
To investigate quantum–classical correspondence, I consider a damped driven harmonic oscillator of mass m and frequency
where γ is a damping constant and
If I denote the classical solution of the system in configuration space as
where
In order to describe quantum solutions of the system, it is useful to introduce an invariant operator which is a powerful tool in elucidating mechanical properties of dynamical systems that are expressed by a time-dependent Hamiltonian like Eq. 1. A linear invariant operator of the system can be derived by means of the Liouville–von Neumann equation and it is given by (see Appendix A)
where
where λ is the eigenvalue and
According to the Lewis–Riesenfeld theory [10, 20], the wave function that satisfies the Schrödinger equation is closely related to the eigenstate of the invariant operator. In fact, the wave function of the system in the coherent state is represented in terms of
where
3 Correspondence Between Quantum and Classical Trajectories
Let us now see whether the expectation values of the position and the momentum operators under this formalism agree with the corresponding classical trajectories or not. Considering that the position operator is represented in terms of
and using Eq. 6, it can be easily verified that
where
where
The above consequence, however, does not mean that the quantum particle (oscillator) follows the exact classical trajectory that is uniquely defined. Quantum mechanics is basically nonlocal and there are numerous possible paths allowed, within the width of a wave packet, for a quantum particle that has a definite initial condition. It is impossible to indicate exactly which path the quantum particle actually follows, but some paths may be more likely than others, especially those close to the classically predicted path. As a consequence of the Ehrenfest’s theorem [24], the trajectory of the quantum particle can be approximated to that of the classical one only when the width of the quantum wave packet is sufficiently narrow. Details of the Ehrenfest’s theorem for a particular case of the system where the oscillator is driven by a sinusoidal force are shown in Ref. [25].
4 Quantum Energy and Its Classical Limit
As pointed out by Hen and Kalev [9] and some other authors [26], obtaining a quantum–classical correspondence from a test performed at the level concerned expectation values is the key for achieving the genuine correspondence. Hence, it is necessary to compare the expectation values of quantum observables with their counterpart classical quantities. I will now analyze the expectation value of the quantum energy which is one of the most common observables in the system. Notice that quantum energy
After representing this operator in terms of
where
For better understanding of the time behavior of Eq. 11, let us consider a specific system which is the cantilever in the tapping mode atomic force microscopy (TMAFM) [30]. This system is widely used as a dynamic imaging technique. For a mechanical description of TMAFM, see Appendix C. The time evolutions of quantum energy for TMAFM are illustrated in Figure 1 using Eq. 11 with comparison to its counterpart classical one. This figure exhibits complete consistency between the quantum energy (with
FIGURE 1. Exact quantum energy (red line), quantum energy with
FIGURE 2. Sawtooth driving force
FIGURE 3. Exact quantum energy (violet line), quantum energy with
For further analysis, let us consider the case where the driving force disappears (
where
5 Uncertainty and The Correspondence Principle
An important feature of quantum mechanics, which distinguishes it from classical mechanics, is the appearance of a minimum uncertainty product between the arbitrary two noncommutative operators. One cannot simultaneously know the values of position and momentum with an arbitrary precision from a quantum measurement, while the classical theory of measurement has nothing to do with such a limitation.
The quantum variance of an observable
Because this consequence is independent of the particular solutions,
6 Other Formalisms and Approaches
There are several other quantum formalisms for describing the damped harmonic oscillator, such as the Lindblad dynamics [35–38], non-Hermitian Hamiltonian dynamics [39–41], and the Schwinger action method [15, 42]. Let’s look into the relatively well-known Lindblad dynamics here. Whereas my approach uses invariant operators
Although the momentum given above seems similar to the physical momentum, it is not exactly the same due to the presence of the additional second term.
In particular, Korsch evaluated the expectation value of
If we denote the expectation value of an observable
where
while
Let us now compare the present result with Korsch’s together with the classical one. The expectation value of
The expectation values
with
Figures 4, 5 are the comparison of the time behavior between
FIGURE 4. Time evolution of the expectation values (EV),
FIGURE 5. Time evolution of
There are lots of different approaches for the classical limit of quantum mechanics with their own viewpoints. The problem of quantum–classical transition has been extensively investigated for the quartic oscillator by Oliveira et al. [29, 43–45]. They argued that quantum–classical correspondence can be achieved via the convergence of three factors, which are large classical actions, the object-environment interaction, and experimentally induced limitations. It was reported by Zurek [46] that the quantum–classical limit is governed by decoherence that takes place through environmental perturbations. As a quantum chaotic system is decohered, it restores classical behavior as a consequence of the destruction of quantum superpositions. Wiebe and Ballentine [47] examined quantum–classical differences by computing the chaotic tumbling of the satellite Hyperion from both classical and quantum points of view regarding the hypothesis of Zurek.
7 Conclusion
Classical limit of quantum mechanics for a driven damped harmonic oscillator has been investigated based on the linear invariant operator. The full wave function of the system was represented in terms of the eigenstate of the linear invariant operator according to the Lewis–Riesenfeld theory [10]. The expectation values of observables, such as position, momentum, and quantum energy, have been derived by using the wave function, and I have compared them with their classical counterparts. From this, it was shown that
The recent trend [48, 49] of the reimplementation of classical mechanics in particle optics using quantum particles is a clear testimony of the close relationship between quantum and classical mechanics. Some essential knowledge of quantum information theory is developed on the basis of classical-like wave properties, while the quantum nature of a physical system is unquestionable especially when nonlocal entanglement is concerned [50]. It may be the very common opinion that every new physical theory should not only precisely describe facts that cannot be covered by existing theories but must also reproduce the predictions of classical mechanics in an appropriate classical limit.
Quantum systems exhibit various nonclassical properties such as entanglement, superposition, nonlocality, and negative Wigner distribution function. While such nonclassicalities are important in the next-generation quantum information science, the description of nonclassical properties is valid and reliable only when the underlying quantum formalism used in such descriptions is precise and complete. A formalism of quantum theory may be acceptable only when it gives classical results in the classical limit (
8 Methods
I considered a time-dependent Hamiltonian, which is composed of the basic CK Hamiltonian and an additional term associated with a time-varying driving force. This Hamiltonian corresponds to a damped driven harmonic oscillator.
The linear invariant operator of the system is constructed from the Liouville–von Neumann equation. The eigenvalue and the eigenstate of the linear invariant operator are derived by solving its eigenvalue equation through a fundamental mathematical procedure. If a system is described by a time-dependent Hamiltonian like the case given here, the eigenstate of the (linear) invariant operator is important because the full wave function of the system is expressed in terms of such an eigenstate [10]. More clearly speaking, the wave function in this case is represented by the eigenstate and a phase factor (see Eq. 6 in the text). Because we now know the formula of the eigenstate, the phase of the wave function can be easily evaluated by means of the Schrödinger equation. In this way, we can derive the full wave function eventually. This wave function is necessary in order to investigate the
The quantum expectation values of observables, such as position, momentum, and the energy operator, are derived using the wave function. By comparing such expectation values with their classical counterparts, the correspondence principle between quantum and classical mechanics is analyzed.
Data Availability Statement
The original contributions presented in the study are included in the article, and further inquiries can be directed to the corresponding author.
Author Contributions
The author confirms being the sole contributor of this work and has approved it for publication.
Funding
This work was supported by the National Research Foundation of Korea(NRF) grant funded by the Korea government(MSIT) (No.: NRF-2021R1F1A1062849).
Conflict of Interest
The author declares that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s Note
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Appendix A: Linear Invariant Operator and its Eigenstate
From a straightforward evaluation of the Liouville-von Neumann equation,
using the Hamiltonian given in Eq. 1 in the text, we can easily derive the linear invariant operator
where
where
Appendix B: Expectation Value of the Energy Operator
I present how to evaluate the expectation value of the energy operator. From a minor evaluation with the energy operator using the expression of
where
with
Appendix C: Cantilever System
Description of the cantilever system appears in Ref. 30. If we denote the effective mass of the cantilever as
where
Appendix D: Damped Harmonic Oscillator with a Sawtooth Force
I regard the damped harmonic oscillator to which applied an external sawtooth force with the period
Appendix E: Expectation Values of and
The expectation values of
where
where
Here,
Keywords: quantum–classical correspondence, classical limit, Caldirola–Kanai Hamiltonian, quantum energy, invariant operator
Citation: Choi JR (2021) Classical Limit of Quantum Mechanics for Damped Driven Oscillatory Systems: Quantum–Classical Correspondence. Front. Phys. 9:670750. doi: 10.3389/fphy.2021.670750
Received: 22 February 2021; Accepted: 24 May 2021;
Published: 03 August 2021.
Edited by:
Robert Gordon, University of Illinois at Chicago, United StatesReviewed by:
Chitra Rangan, University of Windsor, CanadaAdélcio De Oliveira, Universidade Federal de São João del-Rei, Brazil
Copyright © 2021 Choi. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Jeong Ryeol Choi, Y2hvaWFyZG9yQGhhbm1haWwubmV0