Tropical Deep Convection, Cloud Feedbacks and Climate Sensitivity

Stephens, Graeme L.; Shiro, Kathleen A.; Hakuba, Maria Z.; Takahashi, Hanii; Pilewskie, Juliet A.; Andrews, Timothy; Stubenrauch, Claudia J.; Wu, Longtao

doi:10.1007/s10712-024-09831-1

Surv Geophys

2024

DOI: 10.1007/s10712-024-09831-1

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Tropical Deep Convection, Cloud Feedbacks and Climate Sensitivity

Graeme L. Stephens,

Kathleen A. Shiro,

Maria Z. Hakuba

et al.

Abstract: This paper is concerned with how the diabatically-forced overturning circulations of the atmosphere, established by the deep convection within the tropical trough zone (TTZ), first introduced by Riehl and (Malkus) Simpson, in Contr Atmos Phys 52:287–305 (1979), fundamentally shape the distributions of tropical and subtropical cloudiness and the changes to cloudiness as Earth warms. The study first draws on an analysis of a range of observations to understand the connections between the energetics of the TTZ, c… Show more

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Cited by 4 publications

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Trends and Variability in Earth’s Energy Imbalance and Ocean Heat Uptake Since 2005

Hakuba,

Fourest,

Boyer

et al. 2024

Surv Geophys

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Earth’s energy imbalance (EEI) is a fundamental metric of global Earth system change, quantifying the cumulative impact of natural and anthropogenic radiative forcings and feedback. To date, the most precise measurements of EEI change are obtained through radiometric observations at the top of the atmosphere (TOA), while the quantification of EEI absolute magnitude is facilitated through heat inventory analysis, where ~ 90% of heat uptake manifests as an increase in ocean heat content (OHC). Various international groups provide OHC datasets derived from in situ and satellite observations, as well as from reanalyses ingesting many available observations. The WCRP formed the GEWEX-EEI Assessment Working Group to better understand discrepancies, uncertainties and reconcile current knowledge of EEI magnitude, variability and trends. Here, 21 OHC datasets and ocean heat uptake (OHU) rates are intercompared, providing OHU estimates ranging between 0.40 ± 0.12 and 0.96 ± 0.08 W m−2 (2005–2019), a spread that is slightly reduced when unequal ocean sampling is accounted for, and that is largely attributable to differing source data, mapping methods and quality control procedures. The rate of increase in OHU varies substantially between − 0.03 ± 0.13 (reanalysis product) and 1.1 ± 0.6 W m−2 dec−1 (satellite product). Products that either more regularly observe (satellites) or fill in situ data-sparse regions based on additional physical knowledge (some reanalysis and hybrid products) tend to track radiometric EEI variability better than purely in situ-based OHC products. This paper also examines zonal trends in TOA radiative fluxes and the impact of data gaps on trend estimates. The GEWEX-EEI community aims to refine their assessment studies, to forge a path toward best practices, e.g., in uncertainty quantification, and to formulate recommendations for future activities.

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Trends and Variability in Earth’s Energy Imbalance and Ocean Heat Uptake Since 2005

Hakuba,

Fourest,

Boyer

et al. 2024

Surv Geophys

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METEOSAT Long-Term Observations Reveal Changes in Convective Organization Over Tropical Africa and Atlantic Ocean

Roca,

Fiolleau,

John

et al. 2024

Surv Geophys

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In the tropics, deep convection, which is often organized into convective systems, plays a crucial role in the water and energy cycles by significantly contributing to surface precipitation and forming upper-level ice clouds. The arrangement of these deep convective systems, as well as their individual properties, has recently been recognized as a key feature of the tropical climate. Using data from Africa and the tropical Atlantic Ocean as a case study, recent shifts in convective organization have been analyzed through a well-curated, unique record of METEOSAT observations spanning four decades. The findings indicate a significant shift in the occurrence of deep convective systems, characterized by a decrease in large, short-lived systems and an increase in smaller, longer-lived ones. This shift, combined with a nearly constant deep cloud fraction over the same period, highlights a notable change in convective organization. These new observational insights are valuable for refining emerging kilometer-scale climate models that accurately represent individual convective systems but struggle to realistically simulate their overall arrangement.

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A Multi-satellite Perspective on “Hot Tower” Characteristics in the Equatorial Trough Zone

Pilewskie,

Stephens,

Takahashi

et al. 2024

Surv Geophys

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Tropical Deep Convection, Cloud Feedbacks and Climate Sensitivity

Cited by 4 publications

References 81 publications

Trends and Variability in Earth’s Energy Imbalance and Ocean Heat Uptake Since 2005

Trends and Variability in Earth’s Energy Imbalance and Ocean Heat Uptake Since 2005

METEOSAT Long-Term Observations Reveal Changes in Convective Organization Over Tropical Africa and Atlantic Ocean

A Multi-satellite Perspective on “Hot Tower” Characteristics in the Equatorial Trough Zone

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