Influence of Arctic Microlayers and Algal Cultures on Sea Spray Hygroscopicity and the Possible Implications for Mixed-Phase Clouds
Journal article, 2020

As Arctic sea ice cover diminishes, sea spray aerosols (SSA) have a larger potential to be emitted into the Arctic atmosphere. Emitted SSA can contain organic material, but how it affects the ability of particles to act as cloud condensation nuclei (CCN) is still not well understood. Here we measure the CCN-derived hygroscopicity of three different types of aerosol particles: (1) Sea salt aerosols made from artificial seawater, (2) aerosol generated from artificial seawater spiked with diatom species cultured in the laboratory, and (3) aerosols made from samples of sea surface microlayer (SML) collected during field campaigns in the North Atlantic and Arctic Ocean. Samples are aerosolized using a sea spray simulation tank (plunging jet) or an atomizer. We show that SSA containing diatom and microlayer exhibit similar CCN activity to inorganic sea salt with a κ value of ∼1.0. Large-eddy simulation (LES) is then used to evaluate the general role of aerosol hygroscopicity in governing mixed-phase low-level cloud properties in the high Arctic. For accumulation mode aerosol, the simulated mixed-phase cloud properties do not depend strongly on κ, unless the values are lower than 0.4. For Aitken mode aerosol, the hygroscopicity is more important; the particles can sustain the cloud if the hygroscopicity is equal to or higher than 0.4, but not otherwise. The experimental and model results combined suggest that the internal mixing of biogenic organic components in SSA does not have a substantial impact on the cloud droplet activation process and the cloud lifetime in Arctic mixed-phase clouds.

sea surface microlayer

Arctic

sea spray aerosol

mixed-phase clouds

hygroscopicity

CCN

Author

Sigurd Christiansen

Aarhus University

Luisa Ickes

Stockholm University

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Ines Bulatovic

Stockholm University

Caroline Leck

Stockholm University

Benjamin J. Murray

University of Leeds

Allan K. Bertram

University of British Columbia (UBC)

Robert Wagner

Karlsruhe Institute of Technology (KIT)

Elena Gorokhova

Stockholm University

Matthew E. Salter

Stockholm University

Annica M.L. Ekman

Stockholm University

Merete Bilde

Aarhus University

Journal of Geophysical Research: Atmospheres

2169897X (ISSN) 21698996 (eISSN)

Vol. 125 19 e2020JD032808

ModElling the Regional and Global Earth system (MERGE)

Lund University (9945095), 2010-01-01 -- .

Subject Categories

Physical Chemistry

Meteorology and Atmospheric Sciences

Climate Research

DOI

10.1029/2020JD032808

More information

Latest update

10/11/2024