Cellulose in atmospheric particulate matter at rural and urban sites across France and Switzerland

Brighty, Adam Matthew; Jacob, Véronique; Uzu, Gaëlle; Borlaza, Lucille Joanna S.; Conil, Sébastien; Hüglin, Christoph; Grange, Stuart K.; Favez, Olivier; Trébuchon, Cécile; Jaffrezo, Jean-Luc

doi:10.5194/acp-22-6021-2022

Cited by 5 publications

(5 citation statements)

References 69 publications

(80 reference statements)

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“…Briefly, meteorological conditions, such as high temperature and relative humidity, could facilitate the increase in their formation. This factor can also include some fraction of plant debris, identified by cellulose measurements, as discussed in Samaké et al (2019), Borlaza et al (2021a), and Brighty et al (2022).…”

Section: Pmf Solution Description and Pm 10 Contributionsmentioning

confidence: 99%

Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France

et al. 2022

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Abstract. Long-term monitoring at sites with relatively low particulate pollution could provide an opportunity to identify changes in pollutant concentration and potential effects of current air quality policies. In this study, 9-year sampling of PM10 (particles with an aerodynamic diameter below 10 µm) was performed in a rural background site in France (Observatoire Pérenne de l'Environnement or OPE) from 28 February 2012 to 22 December 2020. The positive matrix factorization (PMF) method was used to apportion sources of PM10 based on quantified chemical constituents and specific chemical tracers analysed on collected filters. Oxidative potential (OP), an emerging health metric that measures PM capability to potentially cause anti-oxidant imbalance in the lung, was also measured using two acellular assays: dithiothreitol (DTT) and ascorbic acid (AA). The sources of OP were also estimated using multiple linear regression (MLR) analysis. In terms of mass contribution, the dominant sources are secondary aerosols (nitrate- and sulfate-rich) associated with long-range transport (LRT). However, in terms of OP contributions, the main drivers are traffic, mineral dust, and biomass burning factors. There is also some OP contribution apportioned to the sulfate- and nitrate-rich sources influenced by processes and ageing during LRT that could have encouraged mixing with other anthropogenic sources. The study indicates much lower OP values than in urban areas. A substantial decrease (58 % reduction from the year 2012 to 2020) in the mass contributions from the traffic factor was found, even though this is not clearly reflected in its OP contribution. Nevertheless, the findings in this long-term study at the OPE site could indicate effectiveness of implemented emission control policies, as also seen in other long-term studies conducted in Europe, mainly for urban areas.

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Section: Pmf Solution Description and Pm 10 Contributionsmentioning

confidence: 99%

Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France

et al. 2022

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“…Cellulose was the most abundant organic tracer analyzed (annual mean concentration of 2.2 ± 0.6 ng m -3 ), but levels were much lower than in rural areas of continental Europe (annual mean: 16.3 -284 ng m -3 ) (Sánchez-Ochoa et al, 2007;Brighty et al, 2022), likely due to sparse vegetation at Svalbard. The highest monthly means were seen for June followed by October, but there was no pronounced seasonality for cellulose as seen for the other PBAP tracers (Sect.…”

Section: Cellulosementioning

confidence: 99%

“…Size distribution measurement of cellulose is limited and inconclusive, with highest concentrations reported both for the fine (Puxbaum and Tenze-Kunit, 2003) and the coarse mode (Yttri et al, 2011a;Brighty et al, 2022). Lack of comparable seasonality between nearby sites indicates that local sources prevail (Brighty et al, 2022), but with a certain fraction associated with fine aerosol, LRT is a possibility. Cellulose did not correlate with other PBAP tracers or levoglucosan, corresponding to the findings by Brighty et al (2022), but this does not exclude co-emission (see Sect.…”

Section: Cellulosementioning

confidence: 99%

“…Lack of comparable seasonality between nearby sites indicates that local sources prevail (Brighty et al, 2022), but with a certain fraction associated with fine aerosol, LRT is a possibility. Cellulose did not correlate with other PBAP tracers or levoglucosan, corresponding to the findings by Brighty et al (2022), but this does not exclude co-emission (see Sect. 3.4.1).…”

Section: Cellulosementioning

confidence: 99%

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Composition and sources of carbonaceous aerosol in the European Arctic at Zeppelin Observatory, Svalbard

Yttri

Bäcklund

Conen

et al. 2023

Preprint

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Abstract. Our current understanding of Arctic carbonaceous aerosol (CA) is rudimentary and there is a lack of long-term observations for many components, such as organic aerosol (OA), exceptions to this include equivalent black carbon (eBC) and methane sulfonic acid (MSA). To address this, we analyzed long-term measurements of organic carbon (OC), elemental carbon (EC), and source-specific organic tracers from 2017 to 2020 to constrain CA sources in the rapidly changing Arctic. We also used absorption photometer (aethalometer) measurements to constrain equivalent BC from biomass burning (eBCBB) and fossil fuel combustion (eBCFF) using Positive Matrix Factorization (PMF). Our analysis showed that organic tracers are essential to understand Arctic CA sources. For 2017 to 2020, levoglucosan had a bimodal seasonality, with a signal from residential wood combustion (RWC) in the heating season (H-season; November to May) and from wildfires (WF) in the non-heating season (NH-season; June to October), demonstrating a pronounced inter-annual variability in the WF influence. Biogenic secondary organic aerosol (BSOA) species (2-methyltetrols) from isoprene oxidation appeared only in the NH-season, peaking in July to August. Intrusions of warm air masses from Siberia in summer caused three- and ninefold increases in 2-methyltetrols compared to 2017 to 2018, in 2019 and 2020, respectively, warranting investigation of the local vs. the long-range atmospheric transport (LRT) contribution, as certain Arctic vegetation has highly temperature sensitive biogenic volatile organic compounds (BVOC) emission rates. Primary biological aerosol particles (PBAP) tracers (various sugars and sugar-alcohols) were elevated in the NH-season but evolved differently, whereas cellulose was completely decoupled from the other PBAP tracers. Peak levels of most PBAP tracers and of 2-methyltetrols were associated with WF emissions, demonstrating the importance of measuring a broad spectrum of source specific tracers to understand sources and dynamics of CA. Finally, CA seasonality is heavily influenced by long-range atmospheric transport (LRT) episodes, since background levels are extremely low. E.g., we find the OA peak in the NH-season is as strongly influenced by LRT as is EC during Arctic Haze (AH). Source apportionment of CA by Latin Hypercube Sampling (LHS) showed a mixed contribution from RWC (46 %), fossil fuel (FF) sources (27 %), and BSOA (25 %) in the H-season, whereas BSOA (56 %) prevailed over WF (26 %) and FF (15 %) in the NH-season. Source apportionment of eBC by PMF showed that FF combustion dominated eBC (70 ± 2.7 %), whereas RWC (22 ± 2.7 %) was more abundant than WF (8.0 ± 2.9 %). Modeled BC concentrations from FLEXPART attributed an almost equal share to FF (51 ± 3.1 %) and BB. Both FLEXPART and the PMF analysis concluded that RWC is a more important source than WF. However, with a modeled RWC of 30 ± 4.1 % and WF of 19 ± 2.8 %, FLEXPART suggests relatively higher contributions to eBC from these sources. We find that OA (281 ± 106 ng m−3) is a significant fraction of the Arctic PM10 aerosol particle mass, though less than sea salt aerosol (SSA) (682 ± 46.9 ng m−3) and mineral dust (MD) (613 ± 368 ng m−3) as well as typically non-sea-salt sulfate (nssSO42−) (314 ± 62.6 ng m−3), originating mainly from anthropogenic sources in winter and from natural sources in summer. FF combustion was the prevailing source of eBC, whereas RWC made a larger contribution to eBCBB than WF.

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“…Primary organic aerosols (POAs) arise from direct emissions whose sources are well identified in the literature, being derived from either anthropogenic or biogenic sources. POAs can include organic aerosols originating from natural sources such as spores, fungi, bacteria, viruses, and plant debris − but are more often associated with anthropogenic sources such as combustion of fossil fuels or biofuels and open biomass burning. , Secondary organic aerosols (SOAs) can be formed from the atmospheric oxidation of volatile organic compounds (VOCs) , or originate from various processes such as heterogeneous reactions, photochemistry, and aqueous-phase oxidation. − On the other hand, SOA formation processes are not as well understood, even though the global SOA contribution to organic aerosol (OA) emissions tends toward approximately 50% to 90% . Their complex chemical composition has been the subject of numerous studies over the two past decades.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of the Sources, Precursors, and Processing of Aerosols at a High-Altitude Tropical Site

Dominutti

Chevassus

Baray

et al. 2022

ACS Earth Space Chem.

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This work presents the results from a set of aerosol-and gas-phase measurements collected during the BIO-MAI ̈DO field campaign in Reúnion between March 8 and April 5, 2019. Several offline and online sampling devices were installed at the Mai ̈do Observatory (MO), a remote high-altitude site in the Southern Hemisphere, allowing the physical and chemical characterization of atmospheric aerosols and gases. The evaluation of short-lived gas-phase measurements allows us to conclude that air masses sampled during this period contained little or no anthropogenic influence. The dominance of sulfate and organic species in the submicron fraction of the aerosol is similar to that measured at other coastal sites. Carboxylic acids on PM 10 showed a significant contribution of oxalic acid, a typical tracer of aqueous processed air masses, increasing at the end of the campaign. This result agrees with the positive matrix factorization analysis of the submicron organic aerosol, where more oxidized organic aerosols (MOOAs) dominated the organic aerosol with an increasing contribution toward the end of the campaign. Using a combination of air mass trajectories (model predictions), it was possible to assess the impact of aqueous phase processing on the formation of secondary organic aerosols (SOAs). Our results show how specific chemical signatures and physical properties of air masses, possibly affected by cloud processing, can be identified at Reúnion. These changes in properties are represented by a shift in aerosol size distribution to large diameters and an increased contribution of secondary sulfate and organic aerosols after cloud processing.

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Cellulose in atmospheric particulate matter at rural and urban sites across France and Switzerland

Cited by 5 publications

References 69 publications

Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France

Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France

Composition and sources of carbonaceous aerosol in the European Arctic at Zeppelin Observatory, Svalbard

Evaluation of the Sources, Precursors, and Processing of Aerosols at a High-Altitude Tropical Site

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Cellulose in atmospheric particulate matter at rural and urban sites across France and Switzerland

Cited by 5 publications

References 69 publications

Nine-year trends of PM10 sources and oxidative potential in a rural background site in France

Nine-year trends of PM10 sources and oxidative potential in a rural background site in France

Composition and sources of carbonaceous aerosol in the European Arctic at Zeppelin Observatory, Svalbard

Evaluation of the Sources, Precursors, and Processing of Aerosols at a High-Altitude Tropical Site

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Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France

Nine-year trends of PM₁₀ sources and oxidative potential in a rural background site in France