Tethered balloon measurements reveal enhanced aerosol occurrence aloft interacting with Arctic low-level clouds
Author:
Pilz Christian1ORCID, Cassano John J.234, de Boer Gijs35, Kirbus Benjamin6, Lonardi Michael6, Pöhlker Mira1, Shupe Matthew D.35, Siebert Holger1, Wendisch Manfred6, Wehner Birgit1
Affiliation:
1. 1Atmospheric Microphysics Department, Leibniz Institute for Tropospheric Research (TROPOS), Leipzig, Germany 2. 2National Snow and Ice Data Center (NSIDC), University of Colorado Boulder, Boulder, CO, USA 3. 3Cooperative Institute for Research in Environmental Sciences (CIRES), University of Colorado, Boulder, CO, USA 4. 4Department of Atmospheric and Oceanic Sciences, University of Colorado Boulder, Boulder, CO, USA 5. 5Physical Sciences Laboratory (PSL), National Oceanic and Atmospheric Administration (NOAA), Boulder, CO, USA 6. 6Leipzig Institute for Meteorology (LIM), Leipzig University, Leipzig, Germany
Abstract
Low-level clouds in the Arctic affect the surface energy budget and vertical transport of heat and moisture. The limited availability of cloud-droplet-forming aerosol particles strongly impacts cloud properties and lifetime. Vertical particle distributions are required to study aerosol–cloud interaction over sea ice comprehensively. This article presents vertically resolved measurements of aerosol particle number concentrations and sizes using tethered balloons. The data were collected during the Multidisciplinary drifting Observatory for the Study of Arctic Climate expedition in the summer of 2020. Thirty-four profiles of aerosol particle number concentration were observed in 2 particle size ranges: 12–150 nm (N12−150) and above 150 nm (N>150). Concurrent balloon-borne meteorological measurements provided context for the continuous profiles through the cloudy atmospheric boundary layer. Radiosoundings, cloud remote sensing data, and 5-day back trajectories supplemented the analysis. The majority of aerosol profiles showed more particles above the lowest temperature inversion, on average, double the number concentration compared to below. Increased N12−150 up to 3,000 cm−3 were observed in the free troposphere above low-level clouds related to secondary particle formation. Long-range transport of pollution increased N>150 to 310 cm−3 in a warm, moist air mass. Droplet activation inside clouds caused reductions of N>150 by up to 100%, while the decrease in N12−150 was less than 50%. When low-level clouds were thermodynamically coupled with the surface, profiles showed 5 times higher values of N12−150 in the free troposphere than below the cloud-capping temperature inversion. Enhanced N12−150 and N>150 interacting with clouds were advected above the lowest inversion from beyond the sea ice edge when clouds were decoupled from the surface. Vertically discontinuous aerosol profiles below decoupled clouds suggest that particles emitted at the surface are not transported to clouds in these conditions. It is concluded that the cloud-surface coupling state and free tropospheric particle abundance are crucial when assessing the aerosol budget for Arctic low-level clouds over sea ice.
Publisher
University of California Press
Reference70 articles.
1. Abbatt, JPD, Leaitch, WR, Aliabadi, AA, Bertram, AK, Blanchet, JP, Boivin-Rioux, A, Bozem, H, Burkart, J, Chang, RYW, Charette, J, Chaubey, JP, Christensen, RJ, Cirisan, A, Collins, DB, Croft, B, Dionne, J, Evans, GJ, Fletcher, CG, Galí, M, Ghahreman, R, Girard, E, Gong, W, Gosselin, M, Gourdal, M, Hanna, SJ, Hayashida, H, Herber, AB, Hesaraki, S, Hoor, P, Huang, L, Hussherr, R, Irish, VE, Keita, SA, Kodros, JK, Köllner, F, Kolonjari, F, Kunkel, D, Ladino, LA, Law, K, Levasseur, M, Libois, Q, Liggio, J, Lizotte, M, Macdonald, KM, Mahmood, R, Martin, RV, Mason, RH, Miller, LA, Moravek, A, Mortenson, E, Mungall, EL, Murphy, JG, Namazi, M, Norman, AL, O’Neill, NT, Pierce, JR, Russell, LM, Schneider, J, Schulz, H, Sharma, S, Si, M, Staebler, RM, Steiner, NS, Thomas, JL, von Salzen, K, Wentzell, JJB, Willis, MD, Wentworth, GR, Xu, JW, Yakobi-Hancock, JD. 2019. Overview paper: New insights into aerosol and climate in the Arctic. Atmospheric Chemistry and Physics19(4): 2527–2560. DOI: http://dx.doi.org/10.5194/acp-19-2527-2019. 2. Baccarini, A, Karlsson, L, Dommen, J, Duplessis, P, Vüllers, J, Brooks, IM, Saiz-Lopez, A, Salter, M, Tjernström, M, Baltensperger, U, Zieger, P, Schmale, J.2018. Frequent new particle formation over the high Arctic pack ice by enhanced iodine emissions. Nature Communications11: 4924. DOI: http://dx.doi.org/10.1038/s41467-020-18551-0. 3. Bäumer, D, Vogel, B, Versick, S, Rinke, R, Möhler, O, Schnaiter, M. 2008. Relationship of visibility, aerosol optical thickness and aerosol size distribution in an ageing air mass over South-West Germany. Atmospheric Environment42(5): 989–998. DOI: http://dx.doi.org/10.1016/j.atmosenv.2007.10.017. 4. Beck, LJ, Sarnela, N, Junninen, H, Hoppe, CJM, Garmash, O, Bianchi, F, Riva, M, Rose, C, Peräkylä, O, Wimmer, D, Kausiala, O, Jokinen, T, Ahonen, L, Mikkilä, J, Hakala, J, He, XC, Kontkanen, J, Wolf, KKE, Cappelletti, D, Mazzola, M, Traversi, R, Petroselli, C, Viola, AP, Vitale, V, Lange, R, Massling, A, Nøjgaard, JK, Krejci, R, Karlsson, L, Zieger, P, Jang, S, Lee, K, Vakkari, V, Lampilahti, J, Thakur, RC, Leino, K, Kangasluoma, J, Duplissy, EM, Siivola, E, Marbouti, M, Tham, YJ, Saiz-Lopez, A, Petäjä, T, Ehn, M, Worsnop, DR, Skov, H, Kulmala, M, Kerminen, VM, Sipilä, M. 2021. Differing mechanisms of new particle formation at two Arctic sites. Geophysical Research Letters48(4): e2020GL091334. DOI: http://dx.doi.org/10.1029/2020GL091334. 5. Becker, S, Ehrlich, A, Schäfer, M, Wendisch, M.2023. Airborne observations of the surface cloud radiative effect during different seasons over sea ice and open ocean in the Fram Strait. Atmospheric Chemistry and Physics23(12): 7015–7031. DOI: http://dx.doi.org/10.5194/acp-23-7015-2023.
|
|