Light-enhanced primary marine aerosol production from biologically productive seawater

Long, M. S.; Keene, W. C.; Kieber, David J.; Frossard, A. A.; Russell, Lynn M.; Maben, J. R.; Kinsey, Joanna; Quinn, Patricia K.; Bates, T. S.

doi:10.1002/2014gl059436

Cited by 55 publications

(141 citation statements)

References 48 publications

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“…Longer bubble residence times imply slower bubble terminal rise velocities and thus smaller bubble sizes. Furthermore, smaller bubble sizes equate to a larger concentration of bubbles and a greater bubble bursting rate when all other parameters, such as bubbling air flow, are kept constant [ Keene et al , ; Long et al , ]. Burns and Zhang [] showed that the size of bubbles in aerated seawater decreased in the presence of Triton X‐100.…”

Section: Resultsmentioning

confidence: 99%

“…The addition of peptone and yeast extract is also expected to decrease the surface tension, as observed for proteose‐peptone and yeast extract [ Innocente et al , ; Lima et al , ]. In light of these studies and the fact that aerosol flux increases over time due to growth of phytoplankton and bacteria as was directly observed in the present study and inferred in the field [ Long et al , ], we suggest that biological activity mediates bubble surface tension and the amount and nature of surfactants which in turn alters bubble production in terms of size and concentration and thus alters SSA particle production.…”

Section: Resultsmentioning

confidence: 99%

“…When the SML is disrupted by, e.g., breaking waves and winds, it has been observed that biological and organic material, including microgels, TEP, phytoplankton, bacteria, cellular fragments, and other organic matter, can be dispersed at depth or aerosolized [ Sieburth , ; Bezdek and Carlucci , ; Kuznetsova et al , ; Lewis and Schwartz , ; Aller et al , ; Massel , ; Bigg and Leck , ; Wurl and Holmes , ; Leck and Bigg , ; de Leeuw et al , ; Feng et al , ]. In addition to material concentrated at the uppermost surface layer, a background pool of organic matter in subsurface waters can be scavenged by rising bubbles, brought to the surface and then aerosolized [ Lewis and Schwartz , ; Modini et al , ; Long et al , ; Quinn et al , ]. A recent global modeling study has highlighted the importance of these biogenically produced compounds, especially those which are surface‐active, to the contribution of organic aerosol mass in SSA [ Burrows et al , ].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The influence of marine microbial activities on aerosol production: A laboratory mesocosm study

et al. 2015

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The oceans cover most of the Earth's surface, contain nearly half the total global primary biomass productivity, and are a major source of atmospheric aerosol particles. Here we experimentally investigate links between biological activity in seawater and sea spray aerosol (SSA) flux, a relationship of potential significance for organic aerosol loading and cloud formation over the oceans and thus for climate globally. Bubbles were generated in laboratory mesocosm experiments either by recirculating impinging water jets or glass frits. Experiments were conducted with Atlantic Ocean seawater collected off the eastern end of Long Island, NY, and with artificial seawater containing cultures of bacteria and phytoplankton Thalassiosira pseudonana, Emiliania huxleyi, and Nannochloris atomus. Changes in SSA size distributions occurred during all phases of bacterial and phytoplankton growth, as characterized by cell concentrations, dissolved organic carbon, total particulate carbon, and transparent exopolymer particles (gel-forming polysaccharides representing a major component of biogenic exudate material). Over a 2 week growth period, SSA particle concentrations increased by a factor of less than 2 when only bacteria were present and by a factor of about 3 when bacteria and phytoplankton were present. Production of jet-generated SSA particles of diameter less than 200 nm increased with time, while production of all particle diameters increased with time when frits were used. The implications of a marine biological activity dependent SSA flux are discussed.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The influence of marine microbial activities on aerosol production: A laboratory mesocosm study

et al. 2015

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“…The seawater samples in the chamber were not changed between each replicate run, so differences in the surfactants present at the water surface in subsequent replicate experiments due to bubble scavenging of surfactants cannot be ruled out [Long et al, 2014]. Three replicate experiments were conducted using artificial seawater (Sigma Aldrich, S9883; mass fraction: 55% chloride (Cl − ), 31% Na + , 8% sulfate (SO 2− 4 ), 4% Mg 2+ , 1% K + , 1% Ca 2+ , < 1% other; rehydrated to an absolute salinity of 35 g kg −1 using DIW).…”

Section: Laboratory Sea Spray Chambermentioning

confidence: 99%

Calcium enrichment in sea spray aerosol particles

Salter

Hamacher-Barth

Leck

et al. 2016

Geophysical Research Letters

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Sea spray aerosol particles are an integral part of the Earth's radiation budget. To date, the inorganic composition of nascent sea spray aerosol particles has widely been assumed to be equivalent to the inorganic composition of seawater. Here we challenge this assumption using a laboratory sea spray chamber containing both natural and artificial seawater, as well as with ambient aerosol samples collected over the central Arctic Ocean during summer. We observe significant enrichment of calcium in submicrometer (<1 μm in diameter) sea spray aerosol particles when particles are generated from both seawater sources in the laboratory as well as in the ambient aerosols samples. We also observe a tendency for increasing calcium enrichment with decreasing particle size. Our results suggest that calcium enrichment in sea spray aerosol particles may be environmentally significant with implications for our understanding of sea spray aerosol, its impact on Earth's climate, as well as the chemistry of the marine atmosphere.

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“…The Mediterranean Sea is a highly oligotrophic basin (Bosc et al, 2004;MERMEX group, 2011) with seasonal blooms in the northwest of the basin (D'Ortenzio and Ribera d 'Alcalà, 2009;Siokou-Frangou et al, 2010) and high UVB solar radiation in the stratified surface water during summer time (Sempéré et al, 2015). Additionally, the warm water temperatures of the Mediterranean Sea (compared to colder locations such as the North Atlantic Ocean) could also impact the PMA flux (Jaeglé et al, 2011;Long et al, 2014;Ovadnevaite et al, 2014). In this study, we performed a mesocosm experiment in the Mediterranean Sea to study an artificial bloom, different from the natural bloom period studied in the Schwier et al (2015) study, and tracked the physical and chemical properties of primary marine aerosol that allows us to discuss the parameterization of organic material in PMA provided in earlier works.…”

Section: Introductionmentioning

confidence: 99%

Primary marine aerosol physical flux and chemical composition during a nutrient enrichment experiment in mesocosms in the Mediterranean Sea

et al. 2017

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Abstract. While primary marine aerosol (PMA) is an important part of global aerosol total emissions, its chemical composition and physical flux as a function of the biogeochemical properties of the seawater still remain highly uncharacterized due to the multiplicity of physical, chemical and biological parameters that are involved in the emission process. Here, two nutrient-enriched mesocosms and one control mesocosm, both filled with Mediterranean seawater, were studied over a 3-week period. PMA generated from the mesocosm waters were characterized in term of chemical composition, size distribution and size-segregated cloud condensation nuclei (CCN), as a function of the seawater chlorophyll a (Chl a) concentration, pigment composition, virus and bacteria abundances. The aerosol number size distribution flux was primarily affected by the seawater temperature and did not vary significantly from one mesocosm to the other. The aerosol number size distribution flux was primarily affected by the seawater temperature and did not vary significantly from one mesocosm to the other. Particle number and CCN aerosol fluxes increase by a factor of 2 when the temperature increases from 22 to 32 • C, for all particle submicron sizes. This effect, rarely observed in previous studies, could be specific to oligotrophic waters and/or to this temperature range. In all mesocosms (enriched and control mesocosms), we detected an enrichment of calcium (+500 %) and a deficit in chloride (−36 %) in the submicron PMA mass compared to the literature inorganic composition of the seawater. There are indications that the chloride deficit and calcium enrichment are linked to biological processes, as they are found to be stronger in the enriched mesocosms. This implies a non-linear transfer function between the seawater composition and PMA composition, with comPublished by Copernicus Publications on behalf of the European Geosciences Union. plex processes taking place at the interface during the bubble bursting. We found that the artificial phytoplankton bloom did not affect the CCN activation diameter (D p,50,average = 59.85 ± 3.52 nm and D p,50,average = 93.42 ± 5.14 nm for supersaturations of 0.30 and 0.15 % respectively) or the organic fraction of the submicron PMA (average organic to total mass = 0.31 ± 0.07) compared to the control mesocosm. Contrary to previous observations in natural bloom mesocosm experiments, the correlation between the particle organic fraction and the seawater Chl a was poor, indicating that Chl a is likely not a straightforward proxy for predicting, on a daily scale, PMA organic fraction in models for all types of sea and ocean waters. Instead, the organic fraction of the Aitken mode particles were more significantly linked to heterotrophic flagellates, viruses and dissolved organic carbon (DOC). We stress that different conclusions may be obtained in natural (non-enriched) or non-oligotrophic systems.

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Light-enhanced primary marine aerosol production from biologically productive seawater

Cited by 55 publications

References 48 publications

The influence of marine microbial activities on aerosol production: A laboratory mesocosm study

The influence of marine microbial activities on aerosol production: A laboratory mesocosm study

Calcium enrichment in sea spray aerosol particles

Primary marine aerosol physical flux and chemical composition during a nutrient enrichment experiment in mesocosms in the Mediterranean Sea

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