Exploring subtropical stratocumulus multiple equilibria using a mixed-layer model

TL;DR

This study uses a simplified mixed-layer model to investigate the mechanisms behind multiple equilibria and hysteresis in subtropical stratocumulus clouds, highlighting sensitivities to key parameters and processes.

Contribution

It introduces a computationally efficient mixed-layer model capable of simulating multiple cloud states and analyzing the mechanisms behind stratocumulus cloud hysteresis.

Findings

Decoupling can occur due to entrainment warming or reduced cloud-top cooling.

Critical SST for decoupling is highly sensitive to parameterizations.

Hysteresis exists even without active SST or cloud cover feedbacks.

Abstract

Stratocumulus clouds cover about a fifth of Earths surface, and due to their albedo and low-latitude location, they have a strong effect on Earths radiation budget. Previous studies using Large Eddy Simulations have shown that multiple equilibria (both cloud-covered and cloud-free states) exist as a function of fixed-SST, with relevance to equatorward advected air masses. Multiple equilibria have also been found as a function of atmospheric CO2, with a subtropical SST nearly 10 K higher in the cloud-free state, and with suggested relevance to warm-climate dynamics. In this study, we use a mixed-layer model with an added surface energy balance and the ability to simulate both the cloud-covered and cloud-free states to study both types of multiple equilibria and the corresponding hysteresis. The model's simplicity and computational efficiency allow us to explore the mechanisms critical to the stratocumulus cloud instability and hysteresis as well as isolate key processes that allow for multiple equilibria via mechanism denial experiments not possible with a full-complexity model. For the hysteresis in fixed-SST, we find that decoupling can occur due to either enhanced entrainment warming or a reduction in cloud-top longwave cooling. The critical SST at which decoupling occurs is highly sensitive to precipitation and entrainment parameterizations. In the CO2 hysteresis, decoupling occurs in the simple model used even without the inclusion of an active SST and SST-cloud cover feedbacks, and the width of the hysteresis displays the same sensitivities as the fixed-SST case. Overall, the simple model analysis and results motivate further studies using higher complexity models.