Aerosol properties and aerosol–radiation interactions in clear sky conditions over Germany

Witthuhn, Jonas; Hünerbein, Anja; Filipitsch, Florian; Wacker, Stefan; Meilinger, Stefanie; Deneke, Hartwig

doi:10.5194/acp-2021-517

Cited by 4 publications

(4 citation statements)

References 62 publications

(117 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The radiative transfer simulations were carried out using the TROPOS -Cloud and Aerosol Radiative effect Simulator (hereafter T-CARS). T-CARS is a Python-based environment created to conduct radiative transfer simulations with a particular focus on the investigation of the radiative effects of aerosols, and clouds (Barlakas et al, 2020;Witthuhn et al, 2021;Barrientos-Velasco et al, 2022). The radiative transfer solver used is a 1D single column rapid radiative transfer model (RRTM) for GCM applications (RRTMG;…”

Section: Description Of T-carsmentioning

confidence: 99%

Unlocking potential: A case study on reducing shortwave radiation bias in the Southern Ocean through improved cloud phase retrievals based on machine learning

Schimmel,

Velasco,

Witthuhn

et al. 2024

Preprint

View full text Add to dashboard Cite

There are significant gaps in both experimental and theoretical understanding of mixed-phase clouds, their impacts on the hydrological cycle as well as their effects on atmospheric radiation. Accurately identifying liquid water layers in mixed-phase clouds is crucial for estimating cloud radiative effects. A proof-of-concept study utilizing a machine-learning-based liquid-layer detection method called VOODOO is presented. This method was applied alongside a single-column radiative transfer model to compare downwelling shortwave fluxes of mixed-phase clouds detected by the standard Cloudnet processing chain and VOODOO to ground-based pyranometer observations. Our findings reveal that VOODOO creates more realistic liquid water content distributions and significantly influences profiles of heating rates. Moreover, our study demonstrates a substantial enhancement in the estimation of shortwave cloud radiative effects of VOODOO compared to conventional method Cloudnet. Specifically, we observe a remarkable reduction in the mean absolute error of simulated shortwave radiation at the surface of 70\%, particularly in homogeneous cloud conditions. The mean percentage error of SW cloud radiative effects between Cloudnet and pyranometer observations is 44\%, while VOODOO+Cloudnet reduces this error to 8\%. Overall, our results underscore the potential of VOODOO to provide new insights into deep mixed-phase clouds, which were previously inaccessible using traditional lidar-based remote sensing techniques.

show abstract

Section: Description Of T-carsmentioning

confidence: 99%

Unlocking potential: A case study on reducing shortwave radiation bias in the Southern Ocean through improved cloud phase retrievals based on machine learning

Schimmel,

Velasco,

Witthuhn

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…The radiative transfer simulations were carried out using the TROPOS -Cloud and Aerosol Radiative effect Simulator (hereafter T-CARS). T-CARS is a Python-based environment created to conduct radiative transfer simulations with a particular focus on the investigation of the radiative effects of aerosols, and clouds (Barlakas et al, 2020;Witthuhn et al, 2021;Barrientos-Velasco et al, 2022). The radiative transfer solver used was a 1D single column rapid radiative transfer model (RRTM) for GCM applications (RRTMG; Mlawer et al (1997); Barker et al (2003); Clough et al (2005)).…”

Section: Description Of T-carsmentioning

confidence: 99%

Improved cloud phase retrievals based on remote-sensing observations have the potential to decrease the Southern Ocean shortwave cloud radiation bias

Schimmel

Velasco

Witthuhn³

et al. 2023

Preprint

View full text Add to dashboard Cite

Accurately identifying liquid water layers in mixed-phase clouds is crucial for estimating cloud radiative effects. Lidar-based retrievals are limited in optically thick or multilayer clouds, leading to positive biases in simulated shortwave radiative fluxes. At the same time, general circulation models also tend to overestimate the downwelling shortwave radiation at the surface especially in the Southern Ocean regions. To reduce this SW radiation bias in models, we first need better observational-based retrievals for liquid detection which can later be used for model validation. To address this, a machine-learning-based liquid-layer detection method called VOODOO was employed in a proof-of-concept study using a single column radiative transfer model to compare shortwave cloud radiative effects of liquid-containing clouds detected by Cloudnet and VOODOO to ground-based and satellite observations. Results showed a reduction in shortwave radiation bias, indicating that liquid-layer detection with machine-learning retrievals can improve radiative transfer simulations.

show abstract

“…The TROPOS Cloud and Aerosol Radiative effect Simulator (henceforward T-CARS) is a Python-based framework to carry out radiative transfer simulations with a particular focus on the investigation of the radiative effects of aerosols and clouds. Parts of this framework have already been applied and described in Barlakas et al (2020) and Witthuhn et al (2021). The T-CARS enables the use of various sources for input data, such as atmospheric profiles of trace gases, temperature, humidity, properties of clouds, aerosols, and surface parameters.…”

Section: Radiative Transfer Simulationsmentioning

confidence: 99%

“…As aerosol properties are represented based on the assimilation of MODIS products into the MATCH aerosol transport model, its accuracy in the Arctic determines the accuracy of our findings, and the use of reanalysis properties can have significant biases (e.g. Witthuhn et al, 2021).…”

Section: Cloud Radiative Effect (Cre) and Radiation Budget During Ps106mentioning

confidence: 99%

Radiative closure and cloud effects on the radiation budget based on satellite and shipborne observations during the Arctic summer research cruise, PS106

et al. 2022

Self Cite

View full text Add to dashboard Cite

Abstract. For understanding Arctic climate change, it is critical to quantify and address uncertainties in climate data records on clouds and radiative fluxes derived from long-term passive satellite observations. A unique set of observations collected during the PS106 expedition of the research vessel Polarstern (28 May to 16 July 2017) by the OCEANET facility, is exploited here for this purpose and compared with the CERES SYN1deg ed. 4.1 satellite remote-sensing products. Mean cloud fraction (CF) of 86.7 % for CERES SYN1deg and 76.1 % for OCEANET were found for the entire cruise. The difference of CF between both data sets is due to different spatial resolution and momentary data gaps, which are a result of technical limitations of the set of shipborne instruments. A comparison of radiative fluxes during clear-sky (CS) conditions enables radiative closure (RC) for CERES SYN1deg products by means of independent radiative transfer simulations. Several challenges were encountered to accurately represent clouds in radiative transfer under cloudy conditions, especially for ice-containing clouds and low-level stratus (LLS) clouds. During LLS conditions, the OCEANET retrievals were particularly compromised by the altitude detection limit of 155 m of the cloud radar. Radiative fluxes from CERES SYN1deg show a good agreement with ship observations, having a bias (standard deviation) of −6.0 (14.6) and 23.1 (59.3) W m−2 for the downward longwave (LWD) and shortwave (SWD) fluxes, respectively. Based on CERES SYN1deg products, mean values of the radiation budget and the cloud radiative effect (CRE) were determined for the PS106 cruise track and the central Arctic region (70–90∘ N). For the period of study, the results indicate a strong influence of the SW flux in the radiation budget, which is reduced by clouds leading to a net surface CRE of −8.8 and −9.3 W m−2 along the PS106 cruise and for the entire Arctic, respectively. The similarity of local and regional CRE supports the consideration that the PS106 cloud observations can be representative of Arctic cloudiness during early summer.

show abstract

Aerosol properties and aerosol–radiation interactions in clear sky conditions over Germany

Cited by 4 publications

References 62 publications

Unlocking potential: A case study on reducing shortwave radiation bias in the Southern Ocean through improved cloud phase retrievals based on machine learning

Unlocking potential: A case study on reducing shortwave radiation bias in the Southern Ocean through improved cloud phase retrievals based on machine learning

Improved cloud phase retrievals based on remote-sensing observations have the potential to decrease the Southern Ocean shortwave cloud radiation bias

Radiative closure and cloud effects on the radiation budget based on satellite and shipborne observations during the Arctic summer research cruise, PS106

Contact Info

Product

Resources

About