Aerosol Marine Primary Carbohydrates and Atmospheric Transformation in the Western Antarctic Peninsula

We present ship-borne and land-based measurements of carbohydrate concentrations and patterns in (i) bulk seawater, (ii) sea surface microlayer (SML), and (iii) atmospheric size-resolved aerosol particles (0.05–10 μm) collected in the Western Antarctic Peninsula. In seawater, we find higher combined...

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Bibliographic Details
Main Authors: Sebastian Zeppenfeld (6945245), Manuela van Pinxteren (10647855), Dominik van Pinxteren (8356086), Heike Wex (5620364), Elisa Berdalet (6724805), Dolors Vaqué (10647858), Manuel Dall’Osto (1636573), Hartmut Herrmann (1333227)
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2021
Subjects:
PM
EF
Online Access:https://doi.org/10.1021/acsearthspacechem.0c00351.s001
Description
Summary:We present ship-borne and land-based measurements of carbohydrate concentrations and patterns in (i) bulk seawater, (ii) sea surface microlayer (SML), and (iii) atmospheric size-resolved aerosol particles (0.05–10 μm) collected in the Western Antarctic Peninsula. In seawater, we find higher combined carbohydrates (CCHO) in both the particulate (PCCHO, 13–248 μg L –1 ) and dissolved (DCCHO, 14–294 μg L –1 ) phases than dissolved free carbohydrates (DFCHO, 1.0–17 μg L –1 ). Moderate enrichment factors are found in the SML samples (median EF SML = 1.4 for PCCHO, DCCHO, and DFCHO). In PM 10 atmospheric particles, combined carbohydrates (CCHO aer,PM10 0.2–11.3 ng m –3 ) were preferably found in particles of two size modes (0.05–0.42 and 1.2–10 μm) and strongly correlated with Na + aer,PM10 and wind speed, hence suggesting oceanic emission as their primary source. In contrast to SML samples, very high enrichment factors for CCHO aer relative to the bulk water (EF aer ) were estimated for supermicron (20–4000) and submicron (40–167 000) particles. Notably, the relative atmospheric aerosol monosaccharide compositions strongly differed from the ones sampled in seawater. The prevalence of bacterial monosaccharides (muramic acid, glucosamine) in aerosol particles allows us to suggest a selective consumption and release of polysaccharides by bacteria in the atmosphere. Our results highlight the need to evaluate the role of different ecosystems as aerosol sources around Antarctica.