Vertical characterization of highly oxygenated molecules (HOMs) below and above a boreal forest canopy
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Published:2018-12-10
Issue:23
Volume:18
Page:17437-17450
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ISSN:1680-7324
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Container-title:Atmospheric Chemistry and Physics
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language:en
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Short-container-title:Atmos. Chem. Phys.
Author:
Zha QiaozhiORCID, Yan ChaoORCID, Junninen Heikki, Riva MatthieuORCID, Sarnela Nina, Aalto Juho, Quéléver Lauriane, Schallhart Simon, Dada LubnaORCID, Heikkinen LiineORCID, Peräkylä OtsoORCID, Zou Jun, Rose Clémence, Wang YonghongORCID, Mammarella Ivan, Katul GabrielORCID, Vesala Timo, Worsnop Douglas R., Kulmala MarkkuORCID, Petäjä TuukkaORCID, Bianchi FedericoORCID, Ehn MikaelORCID
Abstract
Abstract. While the role of highly oxygenated molecules (HOMs) in new particle
formation (NPF) and secondary organic aerosol (SOA) formation is not in
dispute, the interplay between HOM chemistry and atmospheric conditions
continues to draw significant research attention. During the Influence of
Biosphere-Atmosphere Interactions on the Reactive Nitrogen budget (IBAIRN)
campaign in September 2016, profile measurements of neutral HOMs below and
above the forest canopy were performed for the first time at the boreal
forest SMEAR II station. The HOM concentrations and composition distributions
below and above the canopy were similar during daytime, supporting a
well-mixed boundary layer approximation. However, much lower nighttime HOM
concentrations were frequently observed at ground level, which was likely due
to the formation of a shallow decoupled layer below the canopy. Near the
ground HOMs were influenced by the changes in the precursors and oxidants and
enhancement of the loss on surfaces in this layer, while the HOMs above the
canopy top were not significantly affected. Our findings clearly illustrate
that near-ground HOM measurements conducted under stably stratified
conditions at this site might only be representative of a small fraction of
the entire nocturnal boundary layer. This could, in turn, influence the
growth of newly formed particles and SOA formation below the canopy where the
large majority of measurements are typically conducted.
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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