Evaluating and improving the retrieval of cloud droplet number: case studies in an urban region and orographic environments in the E. Mediterranean

Romanos Foskinis; Alexandros Papayannis; Athanasios Nenes; Konstantinos Eleftheriadis; Stergios Vratolis; Prodromos Fetfatzis; Maria Gini; Evagelia Diapouli; Olga Zografou; Konstantinos Granakis; Alexis Berne; Anne-Claire Marie Billault-Roux; Mika Komppula; Ville Vakkari

doi:https://doi.org/10.5194/egusphere-egu23-16043

[Back] [Session AS5.7]

EGU23-16043, updated on 26 Feb 2023

https://doi.org/10.5194/egusphere-egu23-16043

EGU General Assembly 2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Evaluating and improving the retrieval of cloud droplet number: case studies in an urban region and orographic environments in the E. Mediterranean

Romanos Foskinis^1,2, Alexandros Papayannis^1,3, Athanasios Nenes^3,4, Konstantinos Eleftheriadis², Stergios Vratolis², Prodromos Fetfatzis², Maria Gini², Evagelia Diapouli², Olga Zografou², Konstantinos Granakis², Alexis Berne⁵, Anne-Claire Marie Billault-Roux⁵, Mika Komppula⁶, and Ville Vakkari^7,8

Romanos Foskinis et al.

¹National Technical University of Athens, Physics, Athens, Greece.
²Environmental Radioactivity Laboratory, N.C.S.R. “Demokritos”, Ag. Paraskevi, 15310, Greece.
³Laboratory of Atmospheric Processes and their Impacts (LAPI), Ecole Polytechnique Fédérale de Lausanne (EPFL), 1015 Lausanne, Switzerland.
⁴Center for the study of Air Quality and Climate Change, Foundation for Research and Technology Hellas, Patras, Greece.
⁵Environmental Remote Sensing Laboratory (LTE), Ecole Polytechnique Fédérale de Lausanne (EPFL), 1015 Lausanne, Switzerland.
⁶Finnish Meteorological Institute, 70211 Kuopio, Finland.
⁷Finnish Meteorological Institute, 00101 Helsinki, Finland.
⁸Atmospheric Chemistry Research Group, Chemical Resource Beneficiation, North-West University, Potchefstroom, South Africa.

It is well established that the Aerosol-Cloud Interaction (ACI) processes play a key-role in global precipitation and are a strong modulator of cloud radiative forcing and climate, and yet remain poorly understood despite decades of research. Aerosol-cloud interactions are one of the most uncertain aspects of anthropogenic climate change (Seinfeld et al., 2016a; IPCC, 2021).

Global datasets on cloud microphysical state – especially droplet number concentration and size distribution – provide important constraints that are required for reducing the ACI uncertainty. Recently, Quaas et al. (2020) showed that satellite remote sensing is the only approach that offers the potential of obtaining global datasets with frequent coverage; current retrieval algorithms, however, carry many uncertainties and require constraints that can only be addressed with in situ and/or ground-based remote sensing observations.

Our study aims to evaluate retrievals of cloud droplet number (Nd), effective radius (r_eff) and optical thickness provided by the CLoud property dAtAset using SEVIRI - Edition 3 (CLAAS-3) cloud products of Satellite Application Facility on Climate Monitoring (CM SAF). For this reason, we used co-located in-situ measurements of aerosols and cloud dynamical properties in conjunction with remote sensing observations at the high-altitude regional background station Hellenic Atmospheric Aerosol and Climate Change (HAC²) during the Cloud-AerosoL InteractionS in the Helmos background TropOsphere (CALISHTO) campaign, which took place from Fall 2021 to Spring 2022 at Mount Helmos in Peloponnese, Greece (https://calishto.panacea-ri.gr/).

In this study, we adopt an approach first applied to droplet retrievals in an urban environment (Foskinis et al. 2022). Ground-based remote sensing instrumentation involved includes a Doppler depolarization lidar (HALO) at 1550 nm to provide the vertical velocity (w) of the air masses, a Doppler cloud radar at 94 GHz (RPG) to provide the equivalent reflectivity factor (Z), and the mean Doppler velocity (VD), and a radiometer at 89 GHz provides the liquid water path (LWP). Furthermore, the in-situ instrumentations employed a co-located scanning Mobility Particle Size (SMPS) measuring the size distribution of submicron aerosol, and a Time-of-Flight Aerosol Chemical Speciation Monitor (ToF-ACSM) to provide the aerosol chemical composition of the aerosols. The in-situ dataset together with the airmass vertical velocity distributions are used as input to a state-of-the art parameterization to predict the droplet number (N_d) in clouds formed in the vicinity of the HAC² station. Retrievals with the the CLAAS-3 cloud properties product from CMSAF are then evaluated with in-situ observations carried out with a cloud probe instrument (PVM-100) and the droplet number calculations.

Compared to our previous study (Foskinis et al. 2022), this study is implemented in a different physical system, where we examined again the dependence of the Spectral Dispersion of Droplets (SDD) on N_d and we found a new optimized expression between SDD-N_d which can be used on the established droplet number retrieval algorithm (Bennartz et al., 2007) for non-precipitating planetary boundary layer clouds in order to mitigate the bias.

How to cite: Foskinis, R., Papayannis, A., Nenes, A., Eleftheriadis, K., Vratolis, S., Fetfatzis, P., Gini, M., Diapouli, E., Zografou, O., Granakis, K., Berne, A., Billault-Roux, A.-C. M., Komppula, M., and Vakkari, V.: Evaluating and improving the retrieval of cloud droplet number: case studies in an urban region and orographic environments in the E. Mediterranean , EGU General Assembly 2023, Vienna, Austria, 24–28 Apr 2023, EGU23-16043, https://doi.org/10.5194/egusphere-egu23-16043, 2023.