Biogenic and biomass burning organic aerosol in a boreal forest at Hyytiälä, Finland, during HUMPPA-COPEC 2010

Corrigan, A. L.; Russell, Lynn M.; Takahama, Satoshi; Äijälä, Mikko; Ehn, Mikael; Junninen, Heikki; Rinne, Janne; Petäj̈ä, Tuukka; Kulmala, Markku; Vogel, Alexander L.; Hoffmann, Thorsten; Ebben, C. J.; Geiger, Franz M.; Chhabra, P. S.; Seinfeld, John H.; Worsnop, Douglas R.; Song, Weihua; Auld, J.; Williams, Jonathan

doi:10.5194/acp-13-12233-2013

Cited by 72 publications

(105 citation statements)

References 116 publications

(178 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…GAINS underestimated the Aitken mode particle concentrations more heavily than AeroCom, by a factor of two to three in Hyytiälä, Värriö and Kpuszta, suggesting that the higher condensation sink associated with higher accumulation mode particle emissions in GAINS had a significant impact on modeled ultra-fine particle number concentrations. In addition, Hyytiälä and Värriö are regions in which BVOC emissions and clean air are the key influencing factors for new particle formation and particle growth (Ruuskanen et al, 2007;Corrigan et al, 2013;Liao et al, 2014). This was reflected in the model results: particle number size distributions in Hyytiälä and Värriö were quite similar between the two simulations based on different anthropogenic emission data sets.…”

Section: Simulated Particle Number Concentrations and Size Distributionssupporting

confidence: 64%

Improving the simulation of global aerosol with size-segregated anthropogenic number emissions

Xausa

Paasonen

Makkonen

et al. 2017

Preprint

View full text Add to dashboard Cite

Climate models are important tools that are used for generating climate change projections, in which aerosol-climate interactions are one of the main sources of uncertainties. In order to quantify aerosol-radiation and aerosolcloud interactions, detailed input of anthropogenic aerosol number emissions is necessary. However, the anthropogenic aerosol number emissions are usually converted from the corresponding mass emissions in precompiled emission inventories through a very simplistic method depending uniquely on chemical composition, particle size and density, which are defined for a few very wide main source sectors. In this work, the anthropogenic particle number emissions converted from the AeroCom mass in the ECHAM-HAM

show abstract

Section: Simulated Particle Number Concentrations and Size Distributionssupporting

confidence: 64%

Improving the simulation of global aerosol with size-segregated anthropogenic number emissions

Xausa

Paasonen

Makkonen

et al. 2017

Preprint

View full text Add to dashboard Cite

show abstract

“…The correlation of total organic acids to OA and m/z 44 was also observed at Hyytiälä, during the spring 2013 (Figures 1e-1h) and HUMPPA-COPEC 2010 studies (Figures 1i-1l) [Corrigan et al, 2013;Vogel et al, 2013]. In this boreal forest, 45-51% of OA mass is accounted for by organic molecules containing at least one acid group.…”

Section: 1002/2015gl064650mentioning

confidence: 72%

“…This is higher than that observed during BEACHON-RoMBAS. Corrigan et al [2013] note that the high OA mass concentration during HUMPPA-COPEC 2010 is due to aged biomass burning plumes advected from forest fires in central Russia, together with unusually high temperatures in Finland during the campaign period leading to enhanced biogenic SOA formation. Thus, the enhanced aging and/or biomass burning impacts may explain the higher organic acid concentration observed during the HUMPPA-COPEC 2010.…”

Section: 1002/2015gl064650mentioning

confidence: 99%

“…Monoterpenes and isoprene are the main biogenic VOCs emitted at this site [Yassaa et al, 2012]. During HUMPPA-COPEC 2010, organic acids were measured using an atmospheric pressure chemical ionization ion trap mass spectrometer (APCI-IT-MS) coupled to a miniature versatile aerosol concentration enrichment system (mVACES) [Vogel et al, 2013] while OA was measured using a compact time-of-flight AMS [Drewnick et al, 2005;Corrigan et al, 2013]. During Hyytiälä-2013, organic acids were measured using a filter inlet for gases and aerosol (FIGAERO) coupled to an HRToF-CIMS [Lopez-Hilfiker et al, 2014] and OA was measured using an aerosol chemical speciation monitor (ACSM) [Ng et al, 2011].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Estimating the contribution of organic acids to northern hemispheric continental organic aerosol

Yatavelli

Mohr

Stark

et al. 2015

Geophysical Research Letters

Self Cite

View full text Add to dashboard Cite

Using chemical ionization mass spectrometry to detect particle‐phase acids and aerosol mass spectrometry (AMS) measurements from Colorado, USA, and two studies in Hyytiälä, Finland, we quantify the fraction of organic aerosol (OA) mass that is composed of molecules with acid functional groups (facid). Molecules containing one or more carboxylic acid functionality contributed approximately 29% (45–51%) of the OA mass in Colorado (Finland). Organic acid mass concentration correlates well with AMS m/z 44 (primarily CO2+), a commonly used marker for highly oxidized aerosol. Using the average empirical relationship between AMS m/z 44 and organic acids in these three studies, together with m/z 44 data from 29 continental northern hemispheric (NH) AMS data sets, we estimate that molecules containing carboxylic acid functionality constitute on average 28% (range 10–50%) of NH continental OA mass with typically higher values at rural/remote sites and during summer and lower values at urban sites and during winter.

show abstract

“…A particularly prominent example is the fire-driven air pollution episode of summer 2010 in western Russia, which affected not only Russia itself but also other parts of Northern Europe [60] and even southern Europe [58], as mentioned earlier. For a boreal forest in Hyytiälä, Finland, using two independent analytical methods and three separate statistical methods, Corrigan et al [61] showed that biomass burning is responsible for 25 % of submicron organic aerosols in the area, especially in the relatively warm and dry months of summer.…”

Section: Aerosolsmentioning

confidence: 99%

Fire Influences on Atmospheric Composition, Air Quality and Climate

Voulgarakis

Field

2015

Curr Pollution Rep

View full text Add to dashboard Cite

Fires impact atmospheric composition through their emissions, which range from long-lived gases to shortlived gases and aerosols. Effects are typically larger in the tropics and boreal regions but can also be substantial in highly populated areas in the northern mid-latitudes. In all regions, fire can impact air quality and health. Similarly, its effect on large-scale atmospheric processes, including regional and global atmospheric chemistry and climate forcing, can be substantial, but this remains largely unexplored. The impacts are primarily realised in the boundary layer and lower free troposphere but can also be noticeable in upper troposphere/lower stratosphere (UT/LS) region, for the most intense fires. In this review, we summarise the recent literature on findings related to fire impact on atmospheric composition, air quality and climate. We explore both observational and modelling approaches and present information on key regions and on the globe as a whole. We also discuss the current and future directions in this area of research, focusing on the major advances in emission estimates, the emerging efforts to include fire as a component in Earth system modelling and the use of modelling to assess health impacts of fire emissions.

show abstract

Biogenic and biomass burning organic aerosol in a boreal forest at Hyytiälä, Finland, during HUMPPA-COPEC 2010

Cited by 72 publications

References 116 publications

Improving the simulation of global aerosol with size-segregated anthropogenic number emissions

Improving the simulation of global aerosol with size-segregated anthropogenic number emissions

Estimating the contribution of organic acids to northern hemispheric continental organic aerosol

Fire Influences on Atmospheric Composition, Air Quality and Climate

Contact Info

Product

Resources

About