Clouds and Climate

The Romps Group at the University of California, Berkeley

Muller and Romps, Acceleration of tropical cyclogenesis by self-aggregation feedbacks, PNAS, 2018
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In high-resolution numerical simulations of the convecting atmosphere, the clouds sometimes clump together into a single blob of intense convection. This phenomenon is referred to as convective aggregation, or convective self-aggregation. Strictly speaking, convective aggregation does not occur in nature: the atmosphere does not collapse all of its convection into a single patch. But, perhaps the feedbacks that are responsible for aggregation in simulations are important for the organization of convection in the real world.

This paper explores the degree to which self-aggregation feedbacks (radiative and surface-flux feedbacks) are important for tropical cyclogenesis. It turns out that the radiative feedbacks are strong enough that they accelerate tropical cyclogenesis by a factor of two or three. In fact, the radiative feedbacks are so strong that the atmosphere can spin up a tropical cyclone with radiative feedbacks alone, i.e., without wind-induced surface heat exchange (WISHE).

Figure 3.  Even without interactive surface fluxes (i.e., fluxes that are larger where the wind speed is higher), tropical cyclogenesis is still possible so long as there is interactive radiation (i.e., radiative heating a function of the water vapor and cloudiness of the atmospheric column).

Even without interactive surface fluxes (i.e., fluxes that are larger where the wind speed is higher), tropical cyclogenesis is still possible so long as there is interactive radiation (i.e., radiative heating a function of the water vapor and cloudiness of the atmospheric column).

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Romps and Oktem, Observing clouds in 4D with multiview stereophotogrammetry, BAMS, 2018  Duan, Wright, and Romps, On the utility (or futility) of using stable water isotopes to constrain the bulk properties of tropical convection, JAMES, 2018