Ice clouds as nonlinear oscillators

TL;DR

This paper presents a simple physical model of ice clouds that behaves as a nonlinear oscillator, revealing bifurcations and limit cycles, and aligns well with real measurements, aiding understanding of ice cloud physics.

Contribution

The study introduces a physically consistent ice cloud model analyzed as a nonlinear oscillator with bifurcations, providing insights into cloud dynamics and scaling behaviors.

Findings

Model exhibits two Hopf bifurcations in relevant parameter regimes.

Limit cycle behavior characterized and scaled.

Model aligns well with real measurement data.

Abstract

Clouds are important features of the atmosphere, determining the energy budget by interacting with incoming solar radiation and outgoing thermal radiation, respectively. For pure ice clouds, the net effect of radiative effect is still unknown. In this study we develop a simple but physically consistent ice cloud model, and analyze it using methods from the theory of dynamical systems. We find that the model constitutes a nonlinear oscillator with two Hopf bifurcations in the relevant parameter regime. In addition to the characterization of the equilibrium states and the occurring limit cycle, we find scaling behaviors of the bifurcations and the limit cycle, reducing the parameter space crucially. Finally, the model shows very good agreement with real measurements, indicating that the main physics is captured and such simple models are helpful tools for investigating ice clouds.