CLARA-A3: The third edition of the AVHRR-based CM SAF climate data record on clouds, radiation and surface albedo covering the period 1979 to 2023

Karlsson, Karl‐Göran; Finkensieper, Stephan; Meirink, Jan Fokke; Riihelä, Aku; Trentmann, Jörg; Akkermans, Tom; Stein, Diana; Devasthale, Abhay; Eliasson, Salomon; Johansson, Erik; Håkansson, Nina; Solodovnik, Irina; Benas, Nikos; Clerbaux, Nicolas; Selbach, N.; Schröder, Marc; Hollmann, Rainer

doi:10.5194/essd-2023-133

Cited by 6 publications

(11 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For example, access to cloud probabilities allows users to utilize cloud information in a stricter mode (i.e., in a clear conservative or cloud conservative mode) for applications that are very sensitive to cloud masking errors. This has enabled safer downstream processing of other CLARA-A3 products such as surface radiation budget components and surface albedo (as is explained in [12]). This detailed evaluation of the improved cloud detection sensitivity (CDS) parameter also has positive implications for other applications.…”

Section: Discussionmentioning

confidence: 99%

Global Cloudiness and Cloud Top Information from AVHRR in the 42-Year CLARA-A3 Climate Data Record Covering the Period 1979–2020

2023

Self Cite

View full text Add to dashboard Cite

This paper investigates the quality of global cloud fraction and cloud-top height products provided by the third edition of the CM SAF cLoud, Albedo and surface RAdiation dataset from the AVHRR data (CLARA-A3) climate data record (CDR) produced by the EUMETSAT Climate Monitoring Satellite Application Facility (CM SAF). Compared with with CALIPSO–CALIOP cloud lidar data and six other cloud CDRs, including the predecessor CLARA-A2, CLARA-A3 has improved cloud detection, especially over ocean surfaces, and improved geographical variation and cloud detection efficiency. In addition, CLARA-A3 exhibits remarkable improvements in the accuracy of its global cloud-top height measurements. For example, in tropical regions, previous underestimations for high-level clouds are reduced by more than 2 km. By taking advantage of more realistic descriptions of global cloudiness, this study attempted to estimate trends in the observable fraction of low-level clouds, acknowledging their importance in producing a net climate cooling effect. The results were generally inconclusive in the tropics, mainly due to the interference of El Nino modes during the period under study. However, the analysis found small negative trends over oceanic surfaces outside the core tropical region. Further studies are needed to verify the significance of these results.

show abstract

Section: Discussionmentioning

confidence: 99%

Global Cloudiness and Cloud Top Information from AVHRR in the 42-Year CLARA-A3 Climate Data Record Covering the Period 1979–2020

2023

Self Cite

View full text Add to dashboard Cite

show abstract

“…CLARA‐A2 offers albedo data from January 1982 to June 2019, and ICDR CLARA‐A2 offers albedo data from January 2019 to the present. After the first product stops updating, the second product can be used as a substitute for the first product (Karlsson et al., 2021). Compared with the on‐site data, the albedo used had a relative accuracy of 3%–15% in ice‐covered regions (Karlsson et al., 2017b).…”

Section: Methodsmentioning

confidence: 99%

“…Therefore, these products could be used for CMIP6 model validation. (b) Surface albedo: The surface albedo data (Karlsson et al, 2017a;Riihelä et al, 2013) After the first product stops updating, the second product can be used as a substitute for the first product (Karlsson et al, 2021). Compared with the on-site data, the albedo used had a relative accuracy of 3%-15% in ice-covered regions (Karlsson et al, 2017b).…”

Section: Validation Data For Cmip6 Modelsmentioning

confidence: 99%

An Ensemble Learning Model Reveals Accelerated Reductions in Snow Depth Over Arctic Sea Ice Under High‐Emission Scenarios

Li,

Ke,

Shen

et al. 2024

JGR Atmospheres

View full text Add to dashboard Cite

There are significant differences in snow depth predictions among different earth system models, and many models underestimate snow depth, restricting their application. Here, major factors influencing snow depth changes in the Coupled Model Intercomparison Project Phase 6 (CMIP6) were identified and evaluated. Based on satellite‐derived snow depth and CMIP6 data, an ensemble learning model based on multiple deep learning methods (hereafter referred to as the Multi‐DL model) was developed to predict future snow depth. According to satellite observations and two Operation IceBridge products, the Multi‐DL model yielded root mean square errors of 7.48, 6.20, and 6.17 cm. A continuous decrease in snow depth was observed from 2002 to 2100, and the rate of decrease accelerated with increasing emissions. Under the highest emission scenario, the first snow‐free year occurred in 2047, within the same decade as the first ice‐free year (2056). The predicted warm season snow depth was sensitive to sea ice velocity, sea ice concentration (siconc), precipitation, sea surface temperature (tos) and albedo, while the predicted cold season snow depth was sensitive to tos, air temperature, and siconc. The above parameters introduce some snow depth uncertainty. This method provides new ideas for predicting snow depth, and the generated snow depth records can provide data support for formulating Arctic‐related policies.

show abstract

“…Data 1) CLARA-A3. The CLARA-A3 data is latest edition of CLARA data record which provides cloud properties and surface radiation parameters derived from the AVHRR sensor onboard the series of polar orbiting NOAA satellites and METOP satellites [15]. It was published by the European Organization for the Exploitation of Meteorological Satellites (EUMETSAT) Satellite Application Facility on Climate Monitoring (CM SAF) in 2023.…”

Section: Methodsmentioning

confidence: 99%

“…However, these products show high uncertainty due to the ways that they are generated. Satellite DSR products from different satellite platforms have different accuracies affected by observation methods, observation periods and retrieval methods [11]- [15]. Data sources and assimilation schemes for the reanalysis data are diverse and input datasets (such as clouds and aerosols) of the assimilation process and model tend to cause systematic errors in the reanalysis DSR products [16], [17].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Downward Shortwave Radiation Products Over the Loess Plateau

Tian,

Zhang,

Duan

et al. 2024

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

View full text Add to dashboard Cite

Downward Shortwave Radiation (DSR) is a key component of the surface energy budget, influencing atmospheric circulation and climate change. DSR products derived from remote sensing observations or generated from reanalysis systems are commonly used as inputs for eco-hydrological and climate models. The Loess Plateau is severely affected by soil erosion, and has been experienced frequent extreme weather events in recent years. Therefore, an accurate DSR product is curial for accurately simulating both climate change or surfaceatmosphere processes on the Loess Plateau. In this study, newly released satellite DSR products Clouds, Albedo and Radiation Edition 3 data (CLARA-A3) and Moderate Resolution Imaging Spectroradiometer land surface Downward Shortwave Radiation Edition 6.1 data (MCD18A1), along with the reanalysis product Land component of the Fifth generation European Centre for Medium-Range Weather Forecasts Reanalysis (ERA5-Land), were evaluated over the Loess Plateau and its surrounding areas. Intraday, daily, monthly and seasonal DSR were evaluated against ground measurements collected from five observation networks. CLARA-A3 outperformed MCD18A1 and ERA5-Land at both monthly and daily scales. The root-mean-square error (RMSE) for monthly (daily) DSR from CLARA-A3, ERA5-Land, and MCD18A1 were 19.31 (31.3) W/m 2 , 25.36 (39.74) W/m 2 , and 25.03 (46.14) W/m 2 , respectively. The study explored potential factors contributing to significant errors in DSR products. Results indicated that snow cover was one possible factor influencing the error in MCD18A1, and CLARA-A3 exhibited greater sensitivity to terrain influence compared to ERA5-Land and MCD18A1. The findings can be the reference for selecting DSR product over the Loess Plateau.

show abstract

CLARA-A3: The third edition of the AVHRR-based CM SAF climate data record on clouds, radiation and surface albedo covering the period 1979 to 2023

Cited by 6 publications

References 42 publications

Global Cloudiness and Cloud Top Information from AVHRR in the 42-Year CLARA-A3 Climate Data Record Covering the Period 1979–2020

Global Cloudiness and Cloud Top Information from AVHRR in the 42-Year CLARA-A3 Climate Data Record Covering the Period 1979–2020

An Ensemble Learning Model Reveals Accelerated Reductions in Snow Depth Over Arctic Sea Ice Under High‐Emission Scenarios

Evaluation of Downward Shortwave Radiation Products Over the Loess Plateau

Contact Info

Product

Resources

About