Gravity Wave Interactions in the Stratocumulus-Topped Boundary Layer

TL;DR

This study uses large-eddy simulations to analyze how gravity waves influence the breakup of stratocumulus-topped boundary layers, identifying critical forcing amplitudes and conditions that lead to cloud breakup or recovery.

Contribution

It introduces a nondimensional framework and systematically investigates the effects of gravity wave forcing amplitude, duration, and wave combinations on boundary layer cloud breakup.

Findings

Breakup occurs when forcing amplitude exceeds 2.5.

Longer duration and wider locality of forcing promote breakup.

Combination of different wave periods increases cloud clearing.

Abstract

This work studies the breakup propensity of the stratocumulus-topped boundary layer (STBL) interacting with gravity waves using large-eddy simulation with a uniform vertical grid of $5$ m and horizontal spacing of $30$ m. A radiative-convective equilibrium (RCE) state is constructed to enforce stationarity in the STBL, and the gravity waves are introduced via a vertical momentum forcing mimicking a packet of plane waves. A nondimensionalization involving the inversion height and mean horizontal base wind as length and velocity scales is proposed to provide a framework to analyze the forcing parameter space. The magnitude of the scaled forcing amplitude ($\mathcal{A}$) is critical in understanding various STBL breakup conditions. Classification of breakup was based on the reduction of the liquid water path for each forced STBL case. We found that breakup did not occur for $\mathcal{A}<1$ and observed modest reductions in cloud for $1<\mathcal{A}<2$, but the deck recovered to the stationary state slowly after the single-period forcing ceased. Fixing $\mathcal{A}\sim 2$ showed that forcings with longer duration and wider locality promote breakup. However, when the forcing is a linear combination of waves of two different periods, the percentage of cleared cloud dramatically increases, though recovery of RCE is still observed in some cases. $\mathcal{A}\geq2.5$ marks a critical threshold by which the STBL breaks up entirely and remains patchy. We further explore the connection between these bulk breakup results and the turbulent state by examining energy budgets and the anisotropy induced by the forcing.