Observing Convective Aggregation

Holloway, Christopher E.; Wing, Allison A.; Bony, Sandrine; Muller, Caroline; Masunaga, Hirohiko; L’Ecuyer, Tristan; Turner, David D.; Zuidema, Paquita

doi:10.1007/s10712-017-9419-1

Cited by 115 publications

(120 citation statements)

References 128 publications

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“…As reviewed carefully by Holloway et al (2017;this issue), the organization of convection has been thought of for many years as being intimately linked to mesoscale systems organized by gravity and other convectively coupled waves (e.g., Mapes 1993) or large-scale circulations. The Earth's atmosphere does exhibit some characteristics of convective self-aggregation, including the tendency of more organized atmospheres to have lower humidity in clear areas, reduced domain-mean high cloudiness, and increased low cloudiness in non-convective areas, with corresponding impacts on surface and radiative fluxes (Tobin et al 2012;Stein et al 2017;Tobin et al 2013).…”

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confidence: 99%

An Observational View of Relationships Between Moisture Aggregation, Cloud, and Radiative Heating Profiles

2017

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Data from several coincident satellite sensors are analyzed to determine the dependence of cloud and precipitation characteristics of tropical regions on the variance in the water vapor field. Increased vapor variance is associated with decreased high cloud fraction and an enhancement of low-level radiative cooling in dry regions of the domain. The result is found across a range of sea surface temperatures and rain rates. This suggests the possibility of an enhanced low-level circulation feeding the moist convecting areas when vapor variance is large. These findings are consistent with idealized models of self-aggregation, in which the aggregation of convection is maintained by a combination of low-level radiative cooling in dry regions and mid-to-upper-level radiative warming in cloudy regions.

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confidence: 99%

An Observational View of Relationships Between Moisture Aggregation, Cloud, and Radiative Heating Profiles

2017

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“…The convective organization established by surface-based precipitation-induced cold pools differs fundamentally from the larger-scale convective self-aggregation discussed elsewhere in this volume (e.g., Holloway et al 2017;Wing et al 2017). In convective selfaggregation, radiative subsidence produces an expansive ([ 1000 km), convectively suppressed, dry region (a ''dry pool'') that is growing in time, neighboring a moist, deep convective region.…”

Section: Introductionmentioning

confidence: 84%

A Survey of Precipitation-Induced Atmospheric Cold Pools over Oceans and Their Interactions with the Larger-Scale Environment

et al. 2017

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Pools of air cooled by partial rain evaporation span up to several hundreds of kilometers in nature and typically last less than 1 day, ultimately losing their identity to the large-scale flow. These fundamentally differ in character from the radiatively-driven dry pools defining convective aggregation. Advancement in remote sensing and in computer capabilities has promoted exploration of how precipitation-induced cold pool processes modify the convective spectrum and life cycle. This contribution surveys current understanding of such cold pools over the tropical and subtropical oceans. In shallow convection with low rain rates, the cold pools moisten, preserving the near-surface equivalent potential temperature or increasing it if the surface moisture fluxes cannot ventilate beyond the new surface layer; both conditions indicate downdraft origin air from within the boundary layer. When rain rates exceed $ 2 mm h À1 , convective-scale downdrafts can bring down drier air of lower equivalent potential temperature from above the boundary layer. The resulting density currents facilitate the lifting of locally thermodynamically favorable air and can impose an arc-shaped mesoscale cloud organization. This organization allows clouds capable of reaching 4-5 km within otherwise dry environments. These are more commonly observed in the northern hemisphere trade wind regime, where the flow to the intertropical 123Surv Geophys (2017) 38:1283-1305 https://doi.org/10.1007/s10712-017-9447-x convergence zone is unimpeded by the equator. Their near-surface air properties share much with those shown from cold pools sampled in the equatorial Indian Ocean. Cold pools are most effective at influencing the mesoscale organization when the atmosphere is moist in the lower free troposphere and dry above, suggesting an optimal range of water vapor paths. Outstanding questions on the relationship between cold pools, their accompanying moisture distribution and cloud cover are detailed further. Near-surface water vapor rings are documented in one model inside but near the cold pool edge; these are not consistent with observations, but do improve with smaller horizontal grid spacings.

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“…Observed maximal radii in fact vary by an order of magnitude, between 10 and 100 km (Black, 1978;Feng et al, 2015;Zuidema et al, 2012). This may also help to better assess models of self-organization, such as those employed in the idealized self-aggregation case (Holloway, 2017;Holloway et al, 2017;Wing & Cronin, 2016;Wing et al, 2017;Yang, 2018). This may also help to better assess models of self-organization, such as those employed in the idealized self-aggregation case (Holloway, 2017;Holloway et al, 2017;Wing & Cronin, 2016;Wing et al, 2017;Yang, 2018).…”

Section: 1029/2019gl082092mentioning

confidence: 94%

Circling in on Convective Organization

Haerter

Böing

Henneberg

et al. 2019

Geophysical Research Letters

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Cold pools (CPs) contribute to convective organization. However, it is unclear by which mechanisms organization occurs. By using a particle method to track CP gust fronts in large eddy simulations, we characterize the basic collision modes between CPs. Our results show that CP interactions, where three expanding gust fronts force an updraft, are key at triggering new convection. Using this, we conceptualize CP dynamics into a parameter‐free mathematical model: circles expand from initially random points in space. Where two expanding circles collide, a stationary front is formed. However, where three expanding circles enclose a single point, a new expanding circle is seeded. This simple model supports three fundamental features of CP dynamics: precipitation cells constitute a spatially interacting system, CPs come in generations, and scales steadily increase throughout the diurnal cycle. Finally, this model provides a framework for how CPs act to cause convective self‐organization, clustering, and extremes.

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Observing Convective Aggregation

Cited by 115 publications

References 128 publications

An Observational View of Relationships Between Moisture Aggregation, Cloud, and Radiative Heating Profiles

An Observational View of Relationships Between Moisture Aggregation, Cloud, and Radiative Heating Profiles

A Survey of Precipitation-Induced Atmospheric Cold Pools over Oceans and Their Interactions with the Larger-Scale Environment

Circling in on Convective Organization

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