English

Work statistics in the periodically driven quartic oscillator: classical versus quantum dynamics

Statistical Mechanics 2020-08-26 v2 Quantum Physics

Abstract

In the thermodynamics of nanoscopic systems the relation between classical and quantum mechanical description is of particular importance. To scrutinize this correspondence we study an anharmonic oscillator driven by a periodic external force with slowly varying amplitude both classically and within the framework of quantum mechanics. The energy change of the oscillator induced by the driving is closely related to the probability distribution of work for the system. With the amplitude λ(t)\lambda(t) of the drive increasing from zero to a maximum λmax\lambda_{max} and then going back to zero again initial and final Hamiltonian coincide. The main quantity of interest is then the probability density P(EfEi)P(E_f|E_i) for transitions from initial energy EiE_i to final energy EfE_f. In the classical case non-diagonal transitions with EfEiE_f\neq E_i mainly arise due to the mechanism of separatrix crossing. We show that approximate analytical results within the pendulum approximation are in accordance with numerical simulations. In the quantum case numerically exact results are complemented with analytical arguments employing Floquet theory. For both classical and quantum case we provide an intuitive explanation for the periodic variation of P(EfEi)P(E_f|E_i) with the maximal amplitude λmax\lambda_{max} of the driving.

Keywords

Cite

@article{arxiv.2004.10479,
  title  = {Work statistics in the periodically driven quartic oscillator: classical versus quantum dynamics},
  author = {Mattes Heerwagen and Andreas Engel},
  journal= {arXiv preprint arXiv:2004.10479},
  year   = {2020}
}

Comments

12 pages, 11 figures

R2 v1 2026-06-23T15:01:21.077Z