The quantum harmonic Otto cycle

TL;DR

This paper reviews the quantum harmonic Otto cycle, highlighting its analytical tractability, experimental realizations, and the study of finite-time dynamics, power-efficiency tradeoffs, and noise effects in quantum heat engines.

Contribution

It provides a comprehensive analysis of the quantum harmonic Otto cycle, including explicit solutions, finite-time operation insights, and the impact of noise, advancing understanding in quantum thermodynamics.

Findings

Explicit solutions for cycle propagators are derived.

Finite-time, frictionless cycles are characterized.

Noise effects on cycle control are illustrated.

Abstract

The quantum Otto cycle serves as a bridge between the macroscopic world of heat engines and the quantum regime of thermal devices composed from a single element. We compile recent studies of the quantum Otto cycle with a harmonic oscillator as a working medium. This model has the advantage that it is analytically trackable. In addition, an experimental realization has been achieved employing a single ion in a harmonic trap. The review is embedded in the field of quantum thermodynamics and quantum open systems. The basic principles of the theory are explained by a specific example illuminating the basic definitions of work and heat. The relation between quantum observables and the state of the system is emphasized. The dynamical description of the cycle is based on a completely positive map formulated as a propagator for each stroke of the engine. Explicit solutions for these propagators are described on a vector space of quantum thermodynamical observables. These solutions which employ different assumptions and techniques are compared. The tradeoff between power and efficiency is the focal point of finite-time-thermodynamics. The dynamical model enables to study finite time cycles limiting time on the adiabtic and the thermalization times. Explicit finite time solutions are found which are frictionless, meaning that no coherence is generated also known as shortcuts to adiabaticity. The transition from frictionless to sudden adiabats is characterized by a non-hermitian degeneracy in the propagator. In addition the influence of noise on the control is illustrated. These results are used to close the cycles either as engines or as refrigerators.