Energy evolution in time-dependent harmonic oscillator
Abstract
The theory of adiabatic invariants has a long history, and very important implications and applications in many different branches of physics, classically and quantally, but is rarely founded on rigorous results. Here we treat the general time-dependent one-dimensional harmonic oscillator, whose Newton equation q + ω2(t) q=0 cannot be solved in general. We follow the time-evolution of an initial ensemble of phase points with sharply defined energy E0 at time t=0 and calculate rigorously the distribution of energy E1 after time t=T, which is fully (all moments, including the variance μ2) determined by the first moment E1. For example, μ2 = E02 [(E1/E0)2 - (ω (T)/ω (0))2]/2, and all higher even moments are powers of μ2, whilst the odd ones vanish identically. This distribution function does not depend on any further details of the function ω (t) and is in this sense universal. In ideal adiabaticity E1 = ω(T) E0/ω(0), and the variance μ2 is zero, whilst for finite T we calculate E1, and μ2 for the general case using exact WKB-theory to all orders. We prove that if ω (t) is of class Cm (all derivatives up to and including the order m are continuous) μ T-(m+1), whilst for class C∞ it is known to be exponential μ (-α T).
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.