Ice nucleating particles over the Eastern Mediterranean measured by unmanned aircraft systems

Jann Schrod,Daniel Weber,Joachim Curtius,Martin Ebert,Albert Ansmann,Christos Keleshis,Holger Baars,Heinz G Bingemer,Michael Pikridas,Jean Sciare,Nikos Mihalopoulos,Mihalis Vrekoussis,Jaqueline Drücke,Eleni Marinou,Bojan Cvetković,Slobodan Nickovic

doi:10.5194/acp-17-4817-2017

Abstract

Abstract. During an intensive field campaign on aerosol, clouds, and ice nucleation in the Eastern Mediterranean in April 2016, we measured the abundance of ice nucleating particles (INPs) in the lower troposphere from unmanned aircraft systems (UASs). Aerosol samples were collected by miniaturized electrostatic precipitators onboard the UASs at altitudes up to 2.5 km. The number of INPs in these samples, which are active in the deposition and condensation modes at temperatures from −20 to −30 °C, were analyzed immediately after collection on site using the ice nucleus counter FRIDGE (FRankfurt Ice nucleation Deposition freezinG Experiment). During the 1-month campaign, we encountered a series of Saharan dust plumes that traveled at several kilometers' altitude. Here we present INP data from 42 individual flights, together with aerosol number concentrations, observations of lidar backscattering, dust concentrations derived by the dust transport model DREAM (Dust Regional Atmospheric Model), and results from scanning electron microscopy. The effect of the dust plumes is reflected by the coincidence of INPs with the particulate matter (PM), the lidar signal, and the predicted dust mass of the model. This suggests that mineral dust or a constituent related to dust was a major contributor to the ice nucleating properties of the aerosol. Peak concentrations of above 100 INPs std L−1 were measured at −30 °C. The INP concentration in elevated plumes was on average a factor of 10 higher than at ground level. Since desert dust is transported for long distances over wide areas of the globe predominantly at several kilometers' altitude, we conclude that INP measurements at ground level may be of limited significance for the situation at the level of cloud formation.

Highlights

Ice nucleating particles (INPs) act as a seed surface for water vapor and liquid water to enable the emergence and growth of ice crystals in the atmosphere
The method we present here to measure INPs from the unmanned aircraft systems (UASs) is based on the offline ice nucleus counter FRIDGE (FRankfurt Ice nucleation Deposition freezinG Experiment) (Schrod et al, 2016)
The atmosphere over Cyprus during the INUIT, BACCHUS, and ACTRIS joint experiment was dominated by advection of dust in the lower and middle troposphere from North Africa, which coincided with high concentrations of INPs

Summary

Introduction

Ice nucleating particles (INPs) act as a seed surface for water vapor and liquid water to enable the emergence and growth of ice crystals in the atmosphere. The process of ice nucleation can occur by immersion, condensation, deposition, or contact freezing (for a detailed explanation, see Vali et al, 2015). Despite their low abundance in the atmosphere, INPs are crucial for the evolution of ice in clouds. In the presence of INPs, water freezes at much higher temperatures by heterogeneous ice nucleation, affecting the formation of clouds, precipitation, and climate. It is a well-known fact that the ice phase plays a key role in the development of precipitation via the Wegener–Bergeron–Findeisen process. Due to this fact, the estimates of radiative climate forcing presented in the IPCC AR5 show the largest error bars and the lowest levels of confidence in the category of cloud adjustments due to aerosol (IPCC, 2013)

Methods

Results

Conclusion