Riccati and Ermakov Equations in Time-Dependent and Time-Independent Quantum Systems

TL;DR

This paper explores the use of Riccati and Ermakov equations to analyze the dynamics of quantum wave packets, revealing connections between classical and quantum systems, invariants, and supersymmetry.

Contribution

It introduces a unified approach using Riccati and Ermakov equations to connect classical and quantum dynamics, invariants, and supersymmetry in quantum systems.

Findings

Derived a dynamical invariant linking classical and quantum dynamics.

Showed the relation between the Ermakov invariant and the Wigner function.

Established connections between factorization, creation/annihilation operators, and supersymmetry.

Abstract

The time-evolution of the maximum and the width of exact analytic wave packet (WP) solutions of the time-dependent Schr\"odinger equation (SE) represents the particle and wave aspects, respectively, of the quantum system. The dynamics of the maximum, located at the mean value of position, is governed by the Newtonian equation of the corresponding classical problem. The width, which is directly proportional to the position uncertainty, obeys a complex nonlinear Riccati equation which can be transformed into a real nonlinear Ermakov equation. The coupled pair of these equations yields a dynamical invariant which plays a key role in our investigation. It can be expressed in terms of a complex variable that linearizes the Riccati equation. This variable also provides the time-dependent parameters that characterize the Green's function, or Feynman kernel, of the corresponding problem. From there, also the relation between the classical and quantum dynamics of the systems can be obtained. Furthermore, the close connection between the Ermakov invariant and the Wigner function will be shown. Factorization of the dynamical invariant allows for comparison with creation/annihilation operators and supersymmetry where the partner potentials fulfil (real) Riccati equations. This provides the link to a nonlinear formulation of time-independent quantum mechanics in terms of an Ermakov equation for the amplitude of the stationary state wave functions combined with a conservation law. Comparison with SUSY and the time-dependent problems concludes our analysis.