Measurements and modeling of surface–atmosphere exchange of microorganisms in Mediterranean grassland

Carotenuto, Federico; Georgiadis, T.; Gioli, Beniamino; Leyronas, Christel; Morris, Cindy E.; Nardino, M.; Wohlfahrt, Georg; Miglietta, Franco

doi:10.5194/acp-17-14919-2017

Cited by 24 publications

(34 citation statements)

References 97 publications

(119 reference statements)

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“…These are not direct measurements, as the estimation depends on the parameterization of the diffusivity coefficient. Varying results were obtained by this technique, which may in many cases be associated with the choice of specific parameterization and the errors associated with the cultivationdependent techniques used to quantify concentrations (Carotenuto et al 2017;Mayol et al 2014;Crawford et al 2014;Huffman et al 2013;Lighthart and Shaffer 1994;Lindemann and Upper 1985;Lindemann et al 1982). The gradient method also tends to fail in specific cases such as under canopies, as in forests, due to the formation of counter gradients (Baldocchi, Hincks, and Meyers 1988).…”

Section: Emission/deposition Fluxes and Long-mentioning

confidence: 99%

Bioaerosol field measurements: Challenges and perspectives in outdoor studies

Šantl-Temkiv

Šikoparija

Maki

et al. 2019

Aerosol Science and Technology

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Outdoor field measurements of bioaerosols are performed within a wide range of basic and applied scientific disciplines, each with its own goals, assumptions, and terminology. This article contains brief reviews of outdoor field bioaerosol research from these diverse interests, with emphasis on perspectives from the atmospheric sciences. The focus is on a high-level discussion of pressing scientific questions, grand challenges, and needs for cross-disciplinary collaboration. The research topics, in which bioaerosol field measurement is important, include (i) atmospheric physics, clouds, climate, and hydrological cycle; (ii) atmospheric chemistry; (iii) airborne allergencontaining particles; (iv) airborne human pathogens and national security; (v) airborne livestock and crop pathogens; and (vi) biogeography and biodiversity. We concisely review bioaerosol impacts and discuss properties that distinguish bioaerosols from abiological aerosols. We give extra focus to regions of specific interest, i.e., forests, polar regions, marine and coastal environments, deserts, urban and rural areas, and summarize key considerations related to bioaerosol measurements, such as of fluxes, of long-range transport, and of sampling from both stationary and vessel-driven platforms. Keeping in mind a series of key scientific questions posed within the diverse communities, we suggest that pressing scientific questions include the following: (i) emission sources and flux estimates; (ii) spatial distribution; (iii) changes in distribution; (iv) atmospheric aging; (v) metabolic activity; (vi) urbanization of allergies; (vii) transport of human pathogens; and (viii) climate-relevant properties.

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Section: Emission/deposition Fluxes and Long-mentioning

confidence: 99%

Bioaerosol field measurements: Challenges and perspectives in outdoor studies

Šantl-Temkiv

Šikoparija

Maki

et al. 2019

Aerosol Science and Technology

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“…Near the ground, typical concentrations of total airborne bacteria range from ∼ 10 2 to 10 6 cells m −3 , depending on the emission source (Burrows et al, 2009b) and on temporal, meteorological, or other environmental conditions influencing its propensity to emit particles to the air (Carotenuto et al, 2017;Huffman et al, 2013;Lighthart, 1997;Lighthart and Shaffer, 1995). Atmospheric mixing tends to homoge-B.…”

Section: Introductionmentioning

confidence: 99%

“…2 Data and assumptions on bacterial processes in clouds 2.1 Atmospheric concentrations of bacterial cells Burrows et al (2009a, b) have summarized data on number concentrations and emission fluxes of bacteria above various ecosystems on the Earth's surface. These ecosystems represent lumped categories based on the original classification by Olson et al (1992).…”

Section: Introductionmentioning

confidence: 99%

The global impact of bacterial processes on carbon mass

Ervens

Amato

2020

Atmos. Chem. Phys.

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Abstract. Many recent studies have identified biological material as a major fraction of ambient aerosol loading. A small fraction of these bioaerosols consist of bacteria that have attracted a lot of attention due to their role in cloud formation and adverse health effects. Current atmospheric models consider bacteria as inert quantities and neglect cell growth and multiplication. We provide here a framework to estimate the production of secondary biological aerosol (SBA) mass in clouds by microbial cell growth and multiplication. The best estimate of SBA formation rates of 3.7 Tg yr−1 is comparable to previous model estimates of the primary emission of bacteria into the atmosphere, and thus this might represent a previously unrecognized source of biological aerosol material. We discuss in detail the large uncertainties associated with our estimates based on the rather sparse available data on bacteria abundance, growth conditions, and properties. Additionally, the loss of water-soluble organic carbon (WSOC) due to microbial processes in cloud droplets has been suggested to compete under some conditions with WSOC loss by chemical (OH) reactions. Our estimates suggest that microbial and chemical processes might lead to a global loss of WSOC of 8–11 and 8–20 Tg yr−1, respectively. While this estimate is very approximate, the analysis of the uncertainties and ranges of all parameters suggests that high concentrations of metabolically active bacteria in clouds might represent an efficient sink for organics. Our estimates also highlight the urgent need for more data concerning microbial concentrations, fluxes, and activity in the atmosphere to evaluate the role of bacterial processes as net aerosol sinks or sources on various spatial and temporal scales.

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“…Most aerobiology studies are restricted to groundbased sampling within the planetary boundary layer (PBL) or focus on extreme events such as heat events and dust storms Jeon et al 2011;Maki et al 2017;Gat et al 2017;Fierer et al 2008;Bowers et al 2013), civilization and health related questions, like disease spread (Park et al 2014;Adams et al 2015;Di Giulio et al 2010;Kelley and Gilbert 2013;Hagan et al 1995;Polymenakou 2012;Griffin 2007;Brown and Hovmøller 2002) or pollen events (Burge 2002;Damialis et al 2015;Ziello et al 2012;Clot 2003;Jäger 2000;Gioulekas et al 2004;Sofiev et al 2013;Hamaoui-Laguel et al 2015). Microbial composition in air masses within the PBL is affected by ground emissions and mixing of air masses (Bowers et al 2011;Carotenuto et al 2017;Burrows et al 2009a, b). Within the PBL (upper boundary around 100-1000 m above ground level, AGL), vertical mixing of air masses over mountainous terrain is driven by ground turbulence, thermal convection and dynamic forcing with strong diurnal and seasonal variations in elevation AGL and mixing force (Rotach et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Microbial composition in seasonal time series of free tropospheric air and precipitation reveals community separation

et al. 2019

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Primary biological aerosols are transported over large distances, are traveling in various media such as dry air masses, clouds or fog, and eventually deposited with dry deposition, especially for larger particles, or precipitation like rain, hail or snow. To investigate relative abundance and diversity of airborne bacterial and fungal communities, samples have been collected with a liquid impinger (Coriolis l) from the top of Mount Sonnblick (3106 m asl, Austrian Alps) from the respective sources under a temporal aspect over four seasons over the year to include all climatic conditions. Bacterial and fungal

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Measurements and modeling of surface–atmosphere exchange of microorganisms in Mediterranean grassland

Cited by 24 publications

References 97 publications

Bioaerosol field measurements: Challenges and perspectives in outdoor studies

Bioaerosol field measurements: Challenges and perspectives in outdoor studies

The global impact of bacterial processes on carbon mass

Microbial composition in seasonal time series of free tropospheric air and precipitation reveals community separation

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