Boundary Layer Clouds and Convection over Subtropical Oceans in our Current and in a Warmer Climate

Nuijens, Louise; Siebesma, A. Pier

doi:10.1007/s40641-019-00126-x

Cited by 57 publications

(62 citation statements)

References 113 publications

(119 reference statements)

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“…Provided the identified resolution-dependence of the cloud cover feedback carries over to other model codes, then it implies that storm resolving models may exaggerate trade wind cumulus cloud feedback. It is also interesting to compare with earlier studies, where LES simulations previously have suggested trade wind cumulus feedback in the range 0.3 and 2.3 Wm −2 K −1 (Bretherton, 2015;Nuijens and Siebesma, 2019), and observational studies up until recently likewise 0.3 -1.7 Wm −2 K −1 (Klein et al, 2017). A recent observational study, however, finds a near-zero trade wind cumulus cloud feedback (Myers et al, submitted), which is in line with our results.…”

Section: Discussionmentioning

confidence: 56%

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Radtke¹,

Mauritsen²,

Hohenegger³

2020

Preprint

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Abstract. The response of shallow trade cumulus clouds to global warming is a leading source of uncertainty to interpretations and projections of the Earth's changing climate. A setup based on the Rain In Cumulus over the Ocean field campaign is used to simulate a shallow trade wind cumulus field with the Icosahedral Non-hydrostatic Large Eddy Model in a control and a perturbed 4 K warmed climate, while degrading horizontal resolution from 100 m to 5 km. As the resolution is coarsened the basic state cloud fraction increases substantially, especially at cloud base, lateral mixing is weaker and cloud tops reach higher. Nevertheless, the overall vertical structure of the cloud layer is surprisingly robust across resolutions. In a warmer climate, cloud cover reduces, alone constituting a positive shortwave cloud feedback: the strength correlates with the amount of basic state cloud fraction, thus is stronger at coarser resolutions. Cloud thickening, resulting from more water vapor availability for condensation in a warmer climate, acts as a compensating feedback, but unlike the cloud cover reduction it is largely resolution independent. Therefore, refining the resolution leads to convergence to a near-zero shallow cumulus feedback. This dependence holds in experiments with enhanced realism including precipitation processes or warming along a moist adiabat instead of uniform warming. Insofar as these findings carry over to other models, they suggest that storm resolving models may exaggerate the trade wind cumulus cloud feedback.

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Section: Discussionmentioning

confidence: 56%

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Radtke¹,

Mauritsen²,

Hohenegger³

2020

Preprint

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“…In contrast, lidars have the potential to detect them much better (Liou and Schotland, 1971;Spinhirne et al, 1982). Space-borne lidars associated with missions such as LITE (Lidar In-space Technology Experiment, Winker et al, 1996), GLASS (Geoscience Laser Altimeter System; Palm et al, 2005;, CALIPSO (Cloud-Aerosol LIdar with Orthogonal Polarization; Winker et al, 2003) or more recently CATS (Cloud-Aerosol Transport System, Yorks et al, 2016) have even revolutionized our knowledge of the global distribution of clouds (Berthier et al, 2008). However, cloud observations from ground-based, airborne or satellite lidar technology were made at the nadir or zenith.…”

Section: Introductionmentioning

confidence: 99%

Trade-wind clouds and aerosols characterized by airborne horizontal lidar measurements during the EUREC<sup>4</sup>A field campaign

Chazette

Totems

Baron

et al. 2020

Earth Syst. Sci. Data

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Abstract. From 23 January to 13 February 2020, 20 manned research flights were conducted over the tropical Atlantic, off the coast of Barbados (13∘30′ N, 58∘30′ W), to characterize the trade-wind clouds generated by shallow convection. These flights were conducted as part of the international EUREC4A (Elucidating the role of cloud–circulation coupling in climate) field campaign. One of the objectives of these flights was to characterize the trade-wind cumuli at their base for a range of meteorological conditions, convective mesoscale organizations and times of the day, with the help of sidewards-staring remote sensing instruments (lidar and radar). This paper presents the datasets associated with horizontal lidar measurements. The lidar sampled clouds from a lateral window of the aircraft over a range of about 8 km, with a horizontal resolution of 15 m, over a rectangle pattern of 20 km by 130 km. The measurements made possible the characterization of the size distribution of clouds near their base and the presence of dust-like aerosols within and above the marine boundary layer. This paper presents the measurements and the different levels of data processing, ranging from the raw Level 1 data (https://doi.org/10.25326/57; Chazette et al., 2020c) to the Level 2 and Level 3 processed data that include a horizontal cloud mask (https://doi.org/10.25326/58; Chazette et al., 2020b) and aerosol extinction coefficients (https://doi.org/10.25326/59; Chazette et al., 2020a). An intermediate level, companion to Level 1 data (Level 1.5), is also available for calibrated and geolocalized data (https://doi.org/10.25326/57; Chazette et al., 2020c).

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“…They showed that shallow convection becomes more vigorous and transports more water vapor from the boundary layer to a free atmosphere in a warmer climate for models in which the shallow convection scheme is active. Brient and Recent studies based on observational relationships and GCMs also tend to support decreases in low cloud cover in warmer climates and the positive low cloud feedback (e.g., Klein et al 2017, Nuijens andSiebesma 2019). It is shown that decrease in low cloud cover in warmer climates is plausible based on CMIP5 multi-model simulation data (Qu et al 2014(Qu et al , 2015 and observational relationships (e.g.…”

Section: Various Studies Related To Future Changes In Mlcsmentioning

confidence: 89%

“…All of these processes affect the vertical profile of the cloud-topped boundary layer. Various physical processes that control MLCs and their complicated interactions are discussed in more detail in some review papers (e.g., Wood 2012, Nuijens andSiebesma 2019).…”

Section: Mechanisms For the Formation And Maintenance Of Mlcsmentioning

confidence: 99%

Marine Low Clouds and their Parameterization in Climate Models

Kawai¹,

Shige

2020

Journal of the Meteorological Society of Japan

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This review paper aims to provide readers with a broad range of meteorological backgrounds with basic information on marine low clouds and the concept of their parameterizations used in global climate models. The first part of the paper presents basic information on marine low clouds and their importance in climate simulations in a comprehensible way. It covers the global distribution and important physical processes related to the clouds, typical examples of observational and modeling studies of such clouds, and the considerable importance of changes in low cloud for climate simulations. In the latter half of the paper, the concept of cloud parameterizations that determine cloud fraction and cloud water content in global climate models, which is sometimes called cloud "macrophysics", is introduced. In the parameterizations, the key element is how to assume or determine the inhomogeneity of water vapor and cloud water content in model grid boxes whose size is several tens to several hundreds of kilometers. Challenges related to cloud representation in such models that must be tackled in the next couple of decades are discussed.

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Boundary Layer Clouds and Convection over Subtropical Oceans in our Current and in a Warmer Climate

Cited by 57 publications

References 113 publications

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Trade-wind clouds and aerosols characterized by airborne horizontal lidar measurements during the EUREC<sup>4</sup>A field campaign

Marine Low Clouds and their Parameterization in Climate Models

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Boundary Layer Clouds and Convection over Subtropical Oceans in our Current and in a Warmer Climate

Cited by 57 publications

References 113 publications

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Shallow Cumulus Cloud Feedback in Large Eddy Simulations – Bridging the Gap to Storm Resolving Models

Trade-wind clouds and aerosols characterized by airborne horizontal lidar measurements during the EUREC&lt;sup&gt;4&lt;/sup&gt;A field campaign

Marine Low Clouds and their Parameterization in Climate Models

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Resources

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Trade-wind clouds and aerosols characterized by airborne horizontal lidar measurements during the EUREC<sup>4</sup>A field campaign