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CHARACTERIZATION OF FINE CARBONACEOUS AEROSOLS FROM THE EASTERN MEDITERRANEAN: CONTRIBUTIONS OF FOSSIL AND NON-FOSSIL CARBON SOURCES

Published online by Cambridge University Press:  08 October 2024

Chandra Mouli Pavuluri*
Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo 060-0819, Japan Institute of Surface-Earth System Science, School of Earth System Science, Tianjin University, Tianjin 300072, China
Nikolaos Mihalopoulos
Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo 060-0819, Japan Environmental Chemical Processes Laboratory, University of Crete, GR-71003, Crete, Greece National Observatory of Athens, Athens, Greece
Masao Uchida
Affiliation:
AMS Facility (NIES-TERRA), Earth System Division, National Institute for Environmental Studies, Tsukuba, Japan
Kanako Mantoku
Affiliation:
AMS Facility (NIES-TERRA), Earth System Division, National Institute for Environmental Studies, Tsukuba, Japan
Toshiyuki Kobayashi
Affiliation:
AMS Facility (NIES-TERRA), Earth System Division, National Institute for Environmental Studies, Tsukuba, Japan
Pingqing Fu
Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo 060-0819, Japan Institute of Surface-Earth System Science, School of Earth System Science, Tianjin University, Tianjin 300072, China
Kimitaka Kawamura*
Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo 060-0819, Japan Now at Chubu Institute for Advanced Studies, Chubu University, Kasugai 487-8501, Japan
*
*Corresponding authors. Emails: [email protected] & [email protected]
*Corresponding authors. Emails: [email protected] & [email protected]
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Abstract

In order to better characterise carbonaceous components in atmospheric aerosols and to assess the contributions of fossil carbon (FC) and non-fossil carbon (NFC) sources and their seasonality in the Eastern Mediterranean, we collected fine (PM1.3) aerosols at a remote marine background site, the Finokalia Research Station, Crete, Greece, over a period of one-year. PM1.3 samples were analysed for elemental carbon (EC), organic carbon (OC), water-soluble OC (WSOC), and stable carbon isotope ratio (δ13CTC) and radiocarbon content (14CTC) (pMC) of total carbon (TC). All the parameters, i.e., PM1.3, δ13CTC and 14CTC showed a clear temporal pattern with higher values in summer and lower values in autumn. The 14CTC ranged from 54.7 to 99.1 pMC with an average of 74.5 pMC during the entire year. The FC content in TC (FCTC) was found to be slightly lower in winter and almost stable in other seasons, whereas the NFC contents (NFCTC) showed a clear seasonality with the highest level in summer followed by spring and the lowest level in winter. Based on these results together with the seasonal distributions of organic tracers, we found that biomass burning (BB) and soil dust are two major sources of the fine aerosols in winter. Although biogenic emissions of VOCs followed by subsequent secondary oxidation processes are significant in summer followed by spring and autumn, pollen is a significant contributor to TC in spring. This study showed that emissions from fossil fuel combustion are significant (25.5%) but minor compared to NFC sources in the eastern Mediterranean.

Type
Conference Paper
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of University of Arizona

INTRODUCTION

Carbonaceous aerosols: elemental carbon (EC) and organic carbon (OC), scatter and absorb the solar radiation and act as cloud condensation nuclei (CCN), seriously affecting the Earth’s climate system (Carmichael et al. Reference Carmichael, Adhikary, Kulkarni, D’Allura, Tang, Streets, Zhang, Bond, Ramanathan and Jamroensan2009; Menon et al. Reference Menon, Hansen, Nazarenko and Luo2002; Novakov and Penner Reference Novakov and Penner1993; Ramanathan et al. Reference Ramanathan, Crutzen, Kiehl and Rosenfeld2001; Rosenfeld et al. Reference Rosenfeld, Zhu, Wang, Zheng, Goren and Yu2019). They also have adverse effects on human health with increased morbidity and mortality (Nel Reference Nel2005; Lin et al. Reference Lin, Arashiro, Clapp, Cui, Sexton, Vizuete, Gold, Jaspers, Fry and Surratt2017; Arfin et al. Reference Arfin, Pillai, Mathew, Tirpude, Bang and Mondal2023) and play an important role in atmospheric chemistry (Kolb and Worsnop Reference Kolb and Worsnop2012). EC directly emits from sources such as fossil fuel combustion, biomass burning (BB) and soil dust (primary). While organic aerosols (OA, generally measured as OC) are emitted directly from primary sources and are also formed by photo-oxidation of volatile organic compounds (VOCs) emitted from both anthropogenic and biogenic sources, these are so called secondary OA (SOA) (Baltensperger et al. Reference Baltensperger, Kalberer, Dommen, Paulsen, Alfarra, Coe, Fisseha, Gascho, Gysel and Nyeki2005; Robinson et al. Reference Robinson, Donahue, Shrivastava, Weitkamp, Sage, Grieshop, Lane, Pierce and Pandis2007; Srivastava et al. Reference Srivastava, Vu, Tong, Shi and Harrison2022). The OA are estimated to account for a large fraction (20–90%) of the submicron aerosols (Kanakidou et al. Reference Kanakidou, Seinfeld, Pandis, Barnes, Dentener, Facchini, Van Dingenen, Ervens, Nenes and Nielsen2005). In addition, both BB emissions and secondary formation and transformation of OA contribute to the high loading of water-soluble OC (WSOC), which further enhances the indirect climate effect of OA. However, the contribution of anthropogenic sources to OA are estimated to be ∼50% at northern mid-latitudes and even higher in densely populated areas such as North America, Western Europe, and East Asia (de Gouw and Jimenez Reference de Gouw and Jimenez2009).

It is well established that the stable carbon isotope ratios of total carbon (δ13CTC) highly depend on its sources, with an obvious difference in the isotopic signatures of the particles derived from different sources. Indeed the particles of marine origin are highly enriched with 13C (Chesselet et al. Reference Chesselet, Fontugne, Buat‐Ménard, Ezat and Lambert1981; Cachier et al. Reference Cachier, Buat‐Menard, Fontugne and Rancher1985; Miyazaki et al. Reference Miyazaki, Kawamura, Jung, Furutani and Uematsu2011), with δ13C that are different from those of the particles of continental origin, especially anthropogenic sources (Turekian Reference Turekian2003; Cao et al. Reference Cao, Chow, Tao, Lee, Watson, Ho, Wang, Zhu and Han2011). Therefore, δ13CTC of aerosols is useful for investigating their origin and has been used in several studies in the last two decades (Rudolph Reference Rudolph2002; Pavuluri et al. Reference Pavuluri, Kawamura, Swaminathan and Tachibana2011b; Dong et al. Reference Dong, Pavuluri, Xu, Wang, Li, Fu and Liu2023).

Although radiocarbon (14C) is well known for providing chronologies through dating method, its application has been extended much further to investigate the fundamental relationships between different compartments of the Earth and climate system (Heaton et al. Reference Heaton, Bard, Bronk Ramsey, Butzin, Kohler, Muscheler, Reimer and Wacker2021). Because 14C decays with a half-life of 5730 years, the 14C is completely absent in carbonaceous aerosols derived from fossil fuel sources, whereas that derived from modern materials (e.g., biomass burning and biological emissions) contain the 14C at contemporary or near contemporary level. Therefore, measurement of the 14C/12C ratio in aerosols has become a unique tool to unambiguously apportion the fossil (FC) and non-fossil carbon (NFC) contents in the atmospheric aerosols (Szidat et al. Reference Szidat, Jenk, Gäggeler, Synal, Fisseha, Baltensperger, Kalberer, Samburova, Reimann and Kasper-Giebl2004; Gustafsson et al. Reference Gustafsson, Kruså, Zencak, Sheesley, Granat, Engström, Praveen, Rao, Leck and Rodhe2009; Pavuluri et al. Reference Pavuluri, Kawamura, Uchida, Kondo and Fu2013; Kirillova et al. Reference Kirillova, Andersson, Tiwari, Srivastava, Bisht and Gustafsson2014; Liu et al. Reference Liu, Mo, Li, Liu, Shen, Ding, Jiang, Cheng, Zhang and Tian2016; Song et al. Reference Song, Zhu, Wei and Peng Pa2019; Li et al. Reference Li, Zhang, Yan, Kang, Xu, Liu, Gao, Chen and He2022; Lim et al. Reference Lim, Hwang, Lee, Czimczik, Xu and Savarino2022). However, the 14C data alone cannot distinguish different sources of the NFC.

A combined study of 14C with elemental and molecular tracers has been shown to be an excellent technique to identify and apportion the different sources of NFC: biomass burning, biological emissions, and SOA from biogenic VOCs (Gelencsér et al. Reference Gelencsér, May, Simpson, Sánchez-Ochoa, Kasper-Giebl, Puxbaum, Caseiro, Pio and Legrand2007; Pavuluri et al. Reference Pavuluri, Kawamura, Uchida, Kondo and Fu2013). However, the sources of carbonaceous aerosols are still poorly understood due to a lack of long-term 14C measurements and/or limited studies on organic molecular tracers (Gilardoni et al. Reference Gilardoni, Vignati, Cavalli, Putaud, Larsen, Karl, Stenström, Genberg, Henne and Dentener2011; Yttri et al. Reference Yttri, Simpson, Bergström, Kiss, Szidat, Ceburnis, Eckhardt, Hueglin, Nøjgaard and Perrino2019), which provide more specific source information: fatty acids are emitted from terrestrial plant wax, vascular plants, microbes, and marine phytoplankton. Levoglucosan is formed during the pyrolysis of cellulose. Biological materials such as pollen, fungi, and bacteria consist of sucrose and mannitol. Isoprene, α-pinene and β-caryophyllene produce SOA upon oxidation in the atmosphere (Simoneit et al. Reference Simoneit, Kobayashi, Mochida, Kawamura, Lee, Lim, Turpin and Komazaki2004; Fu et al. Reference Fu, Kawamura, Pavuluri, Swaminathan and Chen2010; Wang et al. Reference Wang, Pavuluri, Fu, Li, Dong, Xu, Ren, Fan, Li and Zhang2019).

The eastern Mediterranean is considered as an important region for atmospheric aerosol studies, where the aerosol radiative forcing is among the highest in the world, especially in summer (Lelieveld et al. Reference Lelieveld, Berresheim, Borrmann, Crutzen, Dentener, Fischer, Feichter, Flatau, Heland and Holzinger2002; Urdiales-Flores et al. Reference Urdiales-Flores, Zittis, Hadjinicolaou, Osipov, Klingmüller, Mihalopoulos, Kanakidou, Economou and Lelieveld2023). It has also been reported that the radiative cooling effect of aerosols is up to 5 times greater than the warming caused by greenhouse gases (Vrekoussis et al. Reference Vrekoussis, Liakakou, Koçak, Kubilay, Oikonomou, Sciare and Mihalopoulos2005), and the radiative forcing is also varies significantly from season-to-season due to weather conditions and the origin of air masses (Stock et al. Reference Stock, Cheng, Birmili, Massling, Wehner, Müller, Leinert, Kalivitis, Mihalopoulos and Wiedensohler2011). Much attention has been paid to the aerosols of eastern Mediterranean with both short and long term measurements. It has been found that the organic fraction accounts for one third of the submicron aerosols in summer, and its contribution from biomass burning is dominant during March-April and July-September, based on the elemental tracers and mass fractions of carbonaceous components, together with the origins of air masses (Lelieveld et al. Reference Lelieveld, Berresheim, Borrmann, Crutzen, Dentener, Fischer, Feichter, Flatau, Heland and Holzinger2002; Sciare et al. Reference Sciare, Oikonomou, Favez, Liakakou, Markaki, Cachier and Mihalopoulos2008; Paraskevopoulou et al. Reference Paraskevopoulou, Liakakou, Gerasopoulos, Theodosi and Mihalopoulos2014). However, the contributions of FC and NFC to total carbon (TC), the nature of the different FC and NFC sources (biomass burning and biogenic) and the atmospheric processing of aerosols in the eastern Mediterranean troposphere and the entire southern Europe are not yet fully understood.

The aim of this study is to present the characteristics of carbonaceous components, 13C and 14C isotope ratios of TC in fine aerosols (PM1.3) over a one-year period and to apportion the fossil and non-fossil contents of TC in PM1.3 in the eastern Mediterranean troposphere. The results are discussed together with the observations of organic molecular marker species in order to assess the importance of various FC and NFC sources and the atmospheric processing (aging) of carbonaceous aerosols over the Mediterranean region.

EXPERIMENTAL

Aerosol Sampling

PM1.3 sampling was carried out at a remote marine background site, the Finokalia Research Station, characterizing the eastern Mediterranean troposphere and located at 35°32′N, 25º67′E (http://finokalia.chemistry.uoc.gr) on a hill (250 m above sea level) facing the sea on the northern coast of the Island of Crete, Greece (Kouvarakis et al. Reference Kouvarakis, Vrekoussis, Mihalopoulos, Kourtidis, Rappengluck, Gerasopoulos and Zerefos2002). Aerosol samples were collected using a virtual impactor (VI) (Loo and Cork Reference Loo and Cork1988), modified to divide particles into two size fractions: fine (aerodynamic particle diameter Da< 1.3 μm) and coarse particles (Da>1.3 μm). The inlet preceding each VI has a cut-off size of 10 μm. The operational flow rate is 16.7 L min–1 divided into 1.7 and 15.0 minor and major flows, respectively. More details can be found from Koulouri et al. (Reference Koulouri, Saarikoski, Theodosi, Markaki, Gerasopoulos, Kouvarakis, Mäkelä, Hillamo and Mihalopoulos2008). PM1.3 samples were collected on a weekly basis for two consecutive days each from October 2009 to October 2010 (n = 51) using pre-combusted (450°C for 6 hr) quartz fiber filters (Whatman Q-MA; 47 mm in diameter). Filter samples were wrapped in aluminium foil, sealed in plastic boxes and stored in dark at –20°C until chemical analysis.

The aerosol mass in each filter was measured gravimetrically using analytical balance (Mettler-Toledo; AB204) by the difference in mass of the filters before and after sampling, which had been conditioned in a desiccator for approximately 48 hr.

Measurements of Carbonaceous Components and δ13CTC

EC and OC were measured using an EC/OC analyzer (Sunset Laboratory Inc., USA) following the Interagency Monitoring Protected Visual Environments (IMPROVE) thermal/optical evolution protocol and a non-dispersive infrared (NDIR) detector system as described elsewhere (Pavuluri et al. Reference Pavuluri, Kawamura, Aggarwal and Swaminathan2011a). Briefly, the transmittance of laser light (660 nm) through the filter punch (1 cm in diameter) was used to establish the OC/EC split point and hence the OC correction. In addition, the carbonate carbon (CC) was estimated by manual integration of the last (OC4) peak appearing at the maximum temperature step and was subtracted from the total OC (Kaskaoutis et al. Reference Kaskaoutis, Grivas, Theodosi, Tsagkaraki, Paraskevopoulou, Stavroulas, Liakakou, Gkikas, Hatzianastassiou and Wu2020) to avoid any bias in the OC. The analytical errors in duplicate analyses were within 0.7% for OC and 4.3% for EC.

To measure the WSOC, an aliquot of the filter disc (1 cm in diameter) was extracted with 10 ml organic free Milli Q water (18.3 MΩ) under ultrasonication for 20 min. The extracts were then passed through syringe filter (Millex-GV, 0.45 mm, Millipore) and then WSOC was measured using TOC analyzer (Shimadzu TOC-VCSH). The analytical error in duplicate analyses was within 9%.

δ13CTC was determined using an elemental analyzer (EA, Carlo Erba NA 1500) coupled to stable isotope ratio mass spectrometer (irMS, Finnigan MAT Delta Plus) as described elsewhere (Pavuluri et al. Reference Pavuluri, Kawamura, Swaminathan and Tachibana2011b). Briefly, an aliquot of filter packed in a tin cup was injected into EA and the derived gases: CO2 (and N2), were transferred to irMS via ConFlo-II to measure the 13C/12C in TC. The δ13CTC values relative to Pee Dee Belemnite (PDB) were calculated using the following formula:

$${{\rm{\delta }}^{{\rm{13}}}}{{\rm{C}}_{{\rm{TC}}}} = {\rm{ [}}{\left( {^{{\rm{13}}}{\rm{C}}{{\rm{/}}^{{\rm{12}}}}{\rm{C}}} \right)_{{\rm{sample}}}}{\rm{/}}{\left( {^{{\rm{13}}}{\rm{C}}{{\rm{/}}^{{\rm{12}}}}{\rm{C}}} \right)_{{\rm{standard}}}} - {\rm{1]}} \times 1000.$$

The water-insoluble OC (WIOC) was estimated from the difference between OC and WSOC. The sum of EC, OC and CC was considered as TC.

The secondary OC (SOC) was estimated based on the EC tracer method (Castro et al. Reference Castro, Pio, Harrison and Smith1999; Pavuluri et al. Reference Pavuluri, Kawamura, Aggarwal and Swaminathan2011a), although it involves some degree of uncertainty, using the minimum value of OC/EC ratio obtained during the campaign as follows:

$${\left[ {{\rm{SOC}}\left] = \right[{\rm{OC}}} \right]_{{\rm{meas}}}} - {\rm{([EC}}{{\rm{]}}_{{\rm{meas}}}} \times {\left( {{\rm{OC/EC}}} \right)_{{\rm{min}}}}{\rm{)}}$$

The minimum OC/EC ratios of 2.11 for the whole campaign period and 2.65, 2.84, 2.38 and 2.11 for the autumn, winter, spring and summer periods respectively were used as (OC/EC)min and the primary OC (POC) contribution from non-combustion sources was assumed to be negligible. Therefore, the SOC results obtained, and the conclusions drawn from them would not be significantly affected.

Determination of Radiocarbon in TC

The radiocarbon content in the TC (14CTC) of PM1.3 was determined using an accelerator mass spectrometer (AMS), as described elsewhere (Pavuluri et al. Reference Pavuluri, Kawamura, Uchida, Kondo and Fu2013). Briefly, the carbon of a filter disc (1.0 cm in diameter) was combusted at 850°C for 5 hr in a quartz tube (25 cm × 9 mm o.d.) with copper oxide and elemental silver wires, and the CO2 produced was reduced to make a graphite target for AMS analysis in an automated microscale graphitization vacuum line (Uchida et al. Reference Uchida, Kumata, Koike, Tsuzuki, Uchida, Fujiwara and Shibata2010). 14C contents were measured using the 5MV Pelletron accelerator mass spectrometer (15SDH-2, National Electrostatic Cooperation, Middleton, USA) at the NIES-TERRA AMS facility, the National Institute for Environmental Studies (NIES) (Uchida et al. Reference Uchida, Shibata, Yoneda, Kobayashi and Morita2004, Reference Uchida, Mantoku, Kobayashi, Kawamura and Shibata2023). All 14CTC are expressed as percentage of modern (non-fossil) carbon (pMC) (Stuiver and Polach Reference Stuiver and Polach1977), with δ13C correction. The pMC values were calculated by normalisation to the standard material NIST SRM 4990c (HOX II) with a known pMC value (=134.07) as:

$${\rm{pMC}} = \left[ {{{\left( {^{{\rm{14}}}{\rm{C}}{{\rm{/}}^{{\rm{12}}}}{\rm{C}}} \right)}_{{\rm{sample}}}}{\rm{/}}\left( {{\rm{0}}{\rm{.749}} \times {{\left( {^{{\rm{14}}}{\rm{C}}{{\rm{/}}^{{\rm{12}}}}{\rm{C}}} \right)}_{{\rm{HOX}}}}_{\ {\rm{II}}}} \right)} \right] \times {\rm{100}}$$

The carbon amount was quantified manometrically from CO2 gas after combustion. We have not corrected the 14C results for the blank filter. The amount of TC derived from an untreated blank filter was less than 0.42 ± 0.21 µgC (n = 3), which represents at most less than 1% of the TC (50–300 µgC) in each sample, and therefore the blank contribution was considered to be negligible.

Measurements of Organic Molecular Markers

Organic molecular marker species were measured as described elsewhere (Fu et al. Reference Fu, Kawamura, Pavuluri, Swaminathan and Chen2010). Briefly, the organic species were extracted three times with dichloromethane/methanol (2:1; v/v) under ultrasonication for 10 min each and the extracts were concentrated to dryness and then derivatized with 50 mL of N,O-bis-(trimethylsilyl)-trifluoroacetamide (BSTFA) containing 1% trimethylsilyl chloride and 10 mL of pyridine at 70°C for 3 hr. The derivatives were diluted to 140 mL with n-hexane containing 1.43 ng mL−1 of the internal standard (C13 n-alkane) and then analyzed using a capillary gas chromatograph (Hewlett-Packard 6890) coupled to a mass spectrometer (Hewlett-Packard 5973) (GC/MS). The recoveries for the authentic standards and surrogates were better than 80% and the analytical errors in duplicate analyses were less than 10%.

RESULTS AND DISCUSSION

PM1.3 and Carbonaceous Components and Their Temporal Variations

The atmospheric load of PM1.3 and the concentrations of carbonaceous components in the PM1.3 during the whole campaign period (annual) and in each season: autumn (September–November), winter (December–February), spring (March–May) and summer (June–August), are summarized in Table 1. Their temporal variations are depicted in Figure 1. The PM1.3 concentrations varied between 3.36 and 23.9 μgm−3 during the campaign (Table 1) and showed a clear temporal trend with lower values in autumn followed by a gradual increase to maximum in summer and then a sharp decrease in autumn, peaking abruptly in late autumn 2009 and during late winter and early spring 2010 (Figure 1d). On average, the PM1.3 was highest in summer followed by spring and lowest in winter (Table 1).

Table 1 Annual and seasonal summary of the concentrations of carbonaceous components and PM1.3 (μgm−3), δ13CTC (‰) and 14CTC (pMC) in the PM1.3 from Finokalia, Crete Island, Greece, the Eastern Mediterranean during October 2009–October 2010. See text for abbreviations.

Figure 1 Temporal variations in concentrations of (a) EC, CC and WIOC, (b) WSOC and SOC, (c) OC and TC in PM1.3 and (d) PM1.3 mass, (e) δ13CTC and (f) 14CTC (pMC) in the PM1.3 from Finokalia, Crete Island, Greece, the Eastern Mediterranean during October 2009–October 2010. See text for abbreviations.

Temporal variations of TC and all the organic components: OC, WSOC, SOC and WIOC, were very similar to each other and similar to those of PM1.3, except for its abrupt peaks during late winter and early spring (Figure 1b–d). The temporal trend of EC was also generally similar to that of TC and OC, except during the months February, March and September 2010, when EC was almost negligible (Figure 1a, c). On average, all the carbonaceous components: WSOC, OC and TC, as well as EC, were much higher in summer followed by spring and lower in winter, again similar to the seasonality of PM1.3 (Table 1). On the other hand, TC accounted for 9.10 ± 2.91% (range, 3.41 to 16.2%) in PM1.3 during the campaign, with an almost equal contribution in each season: 8.36 ± 2.23%, 8.50 ± 3.68%, 9.00 ± 2.36% and 10.6 ± 3.45% in autumn, winter, spring and summer, respectively. Such similarities in the temporal patterns and seasonality among the carbonaceous components as well as with those of PM1.3 from Crete, suggest that the PM1.3 loading and its composition in the eastern Mediterranean atmosphere were derived from the emissions of the distant source and intensively aged during the long-range atmospheric transport, and hence this study provides the regional scenario.

Interestingly, the temporal pattern of the manually estimated CC was found to be exactly the same as that of the OC (Figure 1a, c). Such similarity suggests that most of the estimated CC in Crete aerosols might be OC, but not the CC. Therefore, it is likely that the OC reported here may be underestimated. In fact, the abundance of WSOC in OC (range: 48.5–131%; ave. 77.5 ± 13.2%) was exceeded the 100% in 2 autumn samples, confirming that the OC was underestimated in this study. However, in order to avoid any possible bias in OC quantification, we considered keeping only the C content estimated from the final step of the inert-mode temperature protocol (OC4 fraction) as CC (Kaskaoutis et al. Reference Kaskaoutis, Grivas, Theodosi, Tsagkaraki, Paraskevopoulou, Stavroulas, Liakakou, Gkikas, Hatzianastassiou and Wu2020) only. The fraction of SOC in OC was up to 97.6% with an average of 64.1 ± 25.7% during the campaign with a higher contribution in winter (70.9 ± 30.5%), followed by autumn (63.2 ± 28.0%), summer (59.6 ± 23.7) and lower in spring (43.5 ± 31.4%). The higher SOC/OC in winter rather than in summer suggests that the secondary processes are more intensive in winter as well and/or that the contribution of EC from major sources such as BB may be much lower in winter and autumn in the eastern Mediterranean.

δ13CTC: Contributions of Continental and Marine Sources

The δ13CTC values in PM1.3 ranged from –26.5 to –21.1‰ during the campaign and their temporal pattern did not show any seasonality, except for significantly higher values in few samples during late winter and early spring (Figure 1e), and their mean values were almost the same in all seasons (Table 1). The δ13CTC in Crete are comparable to the isotopic signatures of the particles emitted by C3 plants biomass burning (BB) (range, –27.4 to –23.8‰) and fossil fuel combustion (–26.5 ± 0.5‰ to –24.2 ± 0.6), but not to those of C4 plants BB (range, –19.9 to –13.8‰) (Turekian et al. Reference Turekian, Macko, Ballentine, Swap and Garstang1998; Widory et al. Reference Widory, Roy, Moullec, Goupil, Cocherie and Guerrot2004). This comparability indicates that the eastern Mediterranean aerosols were mainly derived from the BB and fossil fuel combustion. Furthermore, the stability in the δ13CTC independent to season and TC loadings during the campaign implies that the PM1.3 should have been derived from the same sources and subjected for intensive aging throughout the year.

However, since most of the area in this region is covered by the sea, it is important to estimate the possible contribution of marine sources to the carbonaceous aerosols in this region. It has been reported that δ13CTC of –26.0‰ and –21.0‰ in atmospheric aerosols indicate the marine and continental origin, respectively (Cachier et al. Reference Cachier, Buat‐Menard, Fontugne and Rancher1985; Turekian Reference Turekian2003). As detailed in the previous section, the Crete aerosols were aged and therefore the 13C must be relatively enriched in the TC of PM1.3. Therefore, we used the δ13CTC of −26.5‰ and −21.0‰ as end-members of the continental and marine aerosols to calculate their relative contributions using the following equation:

$$\matrix{ {{\delta ^{{\rm{13}}}}{{\rm{C}}_{{\rm{aerosol}}}} = {f_{{\rm{continental}}}} \times {\delta ^{{\rm{13}}}}{{\rm{C}}_{{\rm{continental}}}} + {f_{{\rm{marine}}}} \times {\delta ^{{\rm{13}}}}{{\rm{C}}_{{\rm{marine}}}}} \cr { {{f_{{\rm{continental}}}} + {f_{{\rm{marine}}}}{\rm{\ = 1}}}}}$$

where f continental and f marine are the fractions of continental and marine carbon, respectively, and δ13Ccontinental and δ13Cmarine are the δ13C values for end members.

The estimated contributions of continental carbon to TC in PM1.3 in the eastern Mediterranean ranged from 2.3–99.5% (ave. 62.3 ± 18.2%) during the campaign, with higher contributions in winter (71.4 ± 23.6%), followed by autumn (64.7 ±17.7%) and summer (61.3 ± 12.7%), and lower contributions in spring (54 ± 17.4%). The average contribution of marine carbon to TC (37.7 ± 18.2%) was close to that reported for marine aerosols at Bermuda (38%) (Turekian Reference Turekian2003) and close to that (45%) at the High Arctic (Narukawa et al. Reference Narukawa, Kawamura, Li and Bottenheim2008), which was influenced by continental and marine sources. Thus, it is clear that the Crete aerosols originated mainly from continental sources such as fossil fuel combustion and BB and could also be of terrestrial biogenic emissions.

Fossil and Non-Fossil Carbon Contents in TC: Implications for Sources

The 14CTC ranged from 54.7 to 99.1 pMC during the campaign (Table 1) and showed a clear temporal pattern with a gradual increase from autumn to winter, followed by a decrease until late spring and then a gradual increase to a maximum in summer (Figure 1f). This temporal pattern was exactly similar to that of TC and other carbonaceous components and also PM1.3, except for a few cases (Figure 1). Furthermore, TC concentrations showed a linear relationship with the 14CTC (Figure 2a) and the correlation coefficient between them found to be relatively strong (r2 = 0.50; p = <0.05). Such similarities among the temporal trends of 14CTC, carbonaceous components and PM1.3, as well as the linear relationship between TC and 14CTC, imply that the temporal changes in the atmospheric loadings of carbonaceous aerosols and even the total PM1.3 in the eastern Mediterranean atmosphere were driven by the changes in their contributions from non-fossil carbon (NFC) sources such as BB and/or biogenic emissions and subsequent secondary processes. While their contributions from fossil carbon (FC) sources such as fossil fuel combustion emissions were almost stable throughout the year.

Figure 2 (a) Scatter plot between the concentrations of TC (μg m−3) and its 14CTC (pMC) and seasonal changes in average concentrations (bars, μg m−3, error bars show the standard deviation) of fossil (FCTC) and non-fossil carbon (NFCTC) contents in TC in PM1.3 from Finokalia, Crete Island, Greece, the eastern Mediterranean.

Seasonal averages of 14CTC were found to be the highest in summer, followed by winter, spring and lower in autumn (Table 1). The second highest abundance of 14CTC in winter is opposite to the seasonal averages of both carbonaceous components and PM1.3, which showed the second highest abundance in spring and the lowest in winter (Table 1). The dissimilarity in the seasonal averages, particularly in winter, despite the similar temporal trends (Figure 1), between 14CTC and the components of PM1.3 also suggests that the NFC sources such as BB must be important, but the amounts of carbonaceous particles and/or gaseous species emitted from these sources were not large in winter. To further investigate the role of NFC sources in the aerosol loading of the eastern Mediterranean atmosphere, we estimated the FC (FCTC) and NFC in TC (NFCTC) contents in the samples analyzed for 14C measurements (n = 16) based on the 14CTC, and their averages are presented in Figure 2b. Interestingly, the averages of FCTC were found to be almost equal in autumn, spring and summer and relatively lower in winter (Figure 2b). On the other hand, the average NFCTC was found to be much higher in summer, followed by spring and autumn, and lower in winter (Figure 2b). However, the amount of NFCTC was much higher than that of FCTC in winter and the average mass ratios of the NFCTC/FCTC were 2.16 ± 0.80 (median, 2.14), 3.33 ± 1.42 (3.33), 2.36 ± 0.67 (2.35) and 21.8 ± 42.8 (5.10), in autumn, winter, spring and summer, respectively. In fact, the higher average mass ratio in summer was driven by an outlier (109).

These results clearly show that the contributions of NFC sources (including biogenic emissions) to atmospheric aerosols are very high compared to those of FC sources and vary significantly from season-to-season, thus controlling the seasonality of the atmospheric loadings of carbonaceous aerosols and also PM1.3 to a greater extent over the eastern Mediterranean. In fact, in contrast to our results, the previous studies reported that the anthropogenic sources such as fossil fuel combustion and BB emissions are the two main sources of aerosols in the eastern Mediterranean region (Lelieveld et al. Reference Lelieveld, Berresheim, Borrmann, Crutzen, Dentener, Fischer, Feichter, Flatau, Heland and Holzinger2002; Sciare et al. Reference Sciare, Bardouki, Moulin and Mihalopoulos2003, Reference Sciare, Oikonomou, Favez, Liakakou, Markaki, Cachier and Mihalopoulos2008), ignoring the role of biogenic emissions and subsequent secondary formation of the aerosols over this region.

We now examine the importance of NFC sources and subsequent secondary formation of carbonaceous aerosols, based on the seasonal changes in concentrations of molecular biomarkers (Figure 3, Pingqing Fu et al. unpublished data, personal communication). The lipid class compounds such as fatty acids are considered as biomarkers for understanding the importance of primary biological sources of atmospheric aerosols, and levoglucosan, formed during the pyrolysis of cellulose, is considered as a biomarker for BB (Simoneit et al. Reference Simoneit, Kobayashi, Mochida, Kawamura, Lee, Lim, Turpin and Komazaki2004; Fu et al. Reference Fu, Kawamura, Pavuluri, Swaminathan and Chen2010). While the sum of species (see Figure 3 caption for list) derived from isoprene, α-pinene, β-caryophyllene is considered as a biomarker for biogenic SOA, sucrose and mannitol are recognized as biomarkers for pollen and soil dust including microbes such as fungi and bacteria (Fu et al. Reference Fu, Kawamura, Pavuluri, Swaminathan and Chen2010; Simoneit et al. Reference Simoneit, Kobayashi, Mochida, Kawamura, Lee, Lim, Turpin and Komazaki2004).

Figure 3 Total concentrations (ng m−3) of biomarker species: fatty acids (∑C8-C32), levoglucosan, isoprene- (∑2-methylglyceric acid+cis-2-methyl-1,3,4-trihydroxy-1-butene+3-methyl-2,3,4-trihydroxy-1-butene+trans-2-methyl-1,3,4-trihydroxy-1-butene+2-methylthreitol+2-methylerythritol) and α-pinene-derived SOA (∑3-hydroxyglutaric acid+pinonic acid+pinic acid+3-methyl-1,2,3-butanetricarboxylic acid) species, and β-caryophyllinic acid, sucrose and mannitol in PM1.3 from Finokalia, Crete Island, Greece, the eastern Mediterranean in autumn (a), winter (b), spring (c) and summer (d).

The molecular distributions of fatty acids showed a strong even carbon number predominance at C16 with Carbon Preference Index (CPI) ranging from 1.99–5.19 (ave. 3.21), suggesting that they are mostly derived from terrestrial higher plant waxes (Fu et al. Reference Fu, Kawamura, Pavuluri, Swaminathan and Chen2010). The fatty acids load was abundant in all seasons with slightly higher levels in spring and summer (Figure 3), suggesting that the contributions of terrestrial biogenic emissions to OA are significant throughout the year with little increase during the growing season. Mean concentrations of levoglucosan were much higher in winter, followed by spring and autumn and lowest in summer, in agreement with Theodosi et al. Reference Theodosi, Panagiotopoulos, Nouara, Zarmpas, Nicolaou, Violaki, Kanakidou, Sempere and Mihalopoulos2018 (Figure 3). While the loadings of SOA derived from isoprene, α-pinene and β-caryophyllene were much higher in summer followed by spring and autumn, and lowest in winter (Figure 3). Sucrose was abundant only in spring and lessor in other seasons, whereas mannitol was much higher in winter followed by spring and summer, and lowest in autumn (Figure 3).

In fact, the levels of NFC were always much higher than that of FC in each season during the campaign (Figure 2b). Despite the minute levels of biogenic SOA and lower levels of fatty acids in winter, the NFC was found to be relatively much higher than those of FC, compared in other seasons during the campaign (Figs. 2b and 3). Therefore, such higher levels of NFC in winter should have been driven mainly by biomass burning and soil dust, in addition to the primary biological emissions. In summer, the loadings of SOA derived from all the biogenic VOCs were much higher than in other seasons (Figure 3) and the NFC levels were almost doubled in summer to those in other seasons (Figure 2b), despite the minute levels of levoglucosan, sucrose and mannitol (Figure 3). Such a comparison between SOA and NFC clearly implies that the increment in the NFC loading must have mainly been driven by the SOA from biogenic VOCs, in addition to the primary biological emissions in summer.

The relatively high levels of NFC in spring and autumn, respectively (Figure 2b), are in consistence with the relatively high loadings of fatty acids, levoglucosan and α-pinene SOA in those two seasons (Figure 3), implying that the emissions from biological sources including pollen, biomass burning and the SOA from terpenes should have been the major contributors in the spring and autumn periods. Such seasonal distributions of NFC and biomarkers together with the comparisons imply that the changes in the atmospheric loading of the NFC and thus the carbonaceous aerosols were mainly controlled by BB and biogenic emissions including soil dust and subsequent secondary formation processes in the eastern Mediterranean.

CONCLUSIONS

This study presents the characteristics of carbonaceous components: EC, CC, WSOC, WIOC, SOC, OC and TC, δ13CTC and 14CTC in PM1.3 collected at a remote marine background site, the Finokalia Research Station on the Island of Crete, Greece in the eastern Mediterranean troposphere over a period of one year. Concentrations of carbonaceous components and PM1.3 as well as δ13CTC and 14CTC showed a clear seasonality during the campaign. The δ13CTC revealed that the fraction of continental carbon is predominant in the eastern Mediterranean aerosols. The contributions of FC sources to carbonaceous aerosols are almost stable throughout the year, except in winter. On the other hand, the contributions of NFC sources to carbonaceous aerosols are much higher than those of the FC sources throughout the year, although they vary from season to season, thus controlling their seasonality. Furthermore, the contributions from BB and soil dust are higher in winter, while those from biogenic emissions and subsequent secondary processes are higher in summer, followed by spring and autumn. Pollen emissions are significant in spring. More importantly, these results show that although fossil fuel combustion emissions are significant, BB and biogenic emissions and their subsequent secondary processes are the main sources of carbonaceous aerosols in the eastern Mediterranean.

ACKNOWLEDGMENTS

This study was in part supported by the Japan Society for the Promotion of Science (JSPS) through a Grant-in-Aid Nos. 21120510 and 24221001 and the Environment Research and Technology Development Fund (B-0903, B-0904) of the Ministry of the Environment, Japan, and National Natural Science Foundation of China (NSFC, Grant-in-Aid Nos.: 41775120 & 42277090), China. Measurements of carbonaceous components and organic molecular markers have been performed at Institute of Low Temperature Science, Hokkaido University, Sapporo 060-0819, and the 14C measurements were performed at the NIES-TERRA AMS Facility, National Institute for Environmental Studies, Tsukuba, Japan.

COMPETING INTERESTS

The authors declare that they have no conflict of interest.

Footnotes

Selected Papers from the 24th Radiocarbon and 10th Radiocarbon & Archaeology International Conferences, Zurich, Switzerland, 11–16 Sept. 2022

References

REFERENCES

Arfin, T, Pillai, AM, Mathew, N, Tirpude, A, Bang, R, Mondal, P. 2023. An overview of atmospheric aerosol and their effects on human health. Environ Sci Pollut Res Int.CrossRefGoogle Scholar
Baltensperger, U, Kalberer, M, Dommen, J, Paulsen, D, Alfarra, MR, Coe, H, Fisseha, R, Gascho, A, Gysel, M, Nyeki, S et al. 2005. Secondary organic aerosols from anthropogenic and biogenic precursors. Faraday Discussions 130.Google ScholarPubMed
Cachier, H, Buat‐Menard, P, Fontugne, M, Rancher, J. 1985. Source terms and source strengths of the carbonaceous aerosol in the tropics. Journal of Atmospheric Chemistry 3, 469489. doi: 10.1007/BF00053872.CrossRefGoogle Scholar
Cao, J-j, Chow, JC, Tao, J, Lee, S-c, Watson, JG, Ho, K-f, Wang, G-h, Zhu, C-s, Han, Y-m. 2011. Stable carbon isotopes in aerosols from chinese cities: influence of fossil fuels. Atmospheric Environment 45(6):13591363.CrossRefGoogle Scholar
Carmichael, GR, Adhikary, B, Kulkarni, S, D’Allura, A, Tang, YH, Streets, D, Zhang, Q, Bond, TC, Ramanathan, V, Jamroensan, A et al. 2009. Asian aerosols: Current and year 2030 distributions and implications to human health and regional climate change. Environ Sci Technol. 43(15):58115817.CrossRefGoogle ScholarPubMed
Castro, L, Pio, C, Harrison, RM, Smith, D. 1999. Carbonaceous aerosol in urban and rural european atmospheres: Estimation of secondary organic carbon concentrations. Atmospheric Environment 33(17):27712781.CrossRefGoogle Scholar
Chesselet, R, Fontugne, M, Buat‐Ménard, P, Ezat, U, Lambert, CE. 1981. The origin of particulate organic carbon in the atmosphere as indicated by its stable carbon isotopic composition. Geophysical Research Letters 8(4), 345348. doi: 10.1029/GL008i004p00345.CrossRefGoogle Scholar
de Gouw, J, Jimenez, JL. 2009. Organic aerosols in the Earth’s atmosphere. Environ Sci Technol. 43(20):76147618.CrossRefGoogle ScholarPubMed
Dong, ZC, Pavuluri, CM, Xu, ZJ, Wang, Y, Li, PS, Fu, PQ, Liu, CQ. 2023. Measurement report: Chemical components and c and n isotoperatios of fine aerosols over tianjin, north china: Year-round observations. Atmos Chem Phys. 23(3):21192143.CrossRefGoogle Scholar
Fu, PQ, Kawamura, K, Pavuluri, CM, Swaminathan, T, Chen, J. 2010. Molecular characterization of urban organic aerosol in Tropical India: Contributions of primary emissions and secondary photooxidation. Atmospheric Chemistry and Physics 10:26632689.CrossRefGoogle Scholar
Gelencsér, A, May, B, Simpson, D, Sánchez-Ochoa, A, Kasper-Giebl, A, Puxbaum, H, Caseiro, A, Pio, C, Legrand, M. 2007. Source apportionment of pm2.5 organic aerosol over Europe: Primary/secondary, natural/anthropogenic, and fossil/biogenic origin. Journal of Geophysical Research 112(D23).CrossRefGoogle Scholar
Gilardoni, S, Vignati, E, Cavalli, F, Putaud, JP, Larsen, BR, Karl, M, Stenström, K, Genberg, J, Henne, S, Dentener, F. 2011. Better constraints on sources of carbonaceous aerosols using a combined 14C – macro tracer analysis in a European rural background site. Atmospheric Chemistry and Physics 11(12):56855700.CrossRefGoogle Scholar
Gustafsson, O, Kruså, M, Zencak, Z, Sheesley, RJ, Granat, L, Engström, E, Praveen, PS, Rao, PSP, Leck, C, Rodhe, H. 2009. Brown clouds over South Asia: Biomass or fossil fuel combustion? Science 323:495498.CrossRefGoogle ScholarPubMed
Heaton, TJ, Bard, E, Bronk Ramsey, C, Butzin, M, Kohler, P, Muscheler, R, Reimer, PJ, Wacker, L. 2021. Radiocarbon: A key tracer for studying Earth’s dynamo, climate system, carbon cycle, and sun. Science 374(6568):eabd7096.CrossRefGoogle ScholarPubMed
Kanakidou, M, Seinfeld, JH, Pandis, SN, Barnes, I, Dentener, FJ, Facchini, MC, Van Dingenen, R, Ervens, B, Nenes, A, Nielsen, CJ et al. 2005. Organic aerosol and global climate modelling: A review. Atmospheric Chemistry and Physics 5:10531123.CrossRefGoogle Scholar
Kaskaoutis, DG, Grivas, G, Theodosi, C, Tsagkaraki, M, Paraskevopoulou, D, Stavroulas, I, Liakakou, E, Gkikas, A, Hatzianastassiou, N, Wu, C. 2020. Carbonaceous aerosols in contrasting atmospheric environments in Greek cities: Evaluation of the ec-tracer methods for secondary organic carbon estimation. Atmosphere 11(2):161.CrossRefGoogle Scholar
Kirillova, EN, Andersson, A, Tiwari, S, Srivastava, AK, Bisht, DS, Gustafsson, Ö. 2014. Water-soluble organic carbon aerosols during a full new delhi winter: Isotope-based source apportionment and optical properties. Journal of Geophysical Research: Atmospheres 119(6):34763485.CrossRefGoogle Scholar
Kolb, CE, Worsnop, DR. 2012. Chemistry and composition of atmospheric aerosol particles. Annu Rev Phys Chem. 63:471491.CrossRefGoogle Scholar
Koulouri, E, Saarikoski, S, Theodosi, C, Markaki, Z, Gerasopoulos, E, Kouvarakis, G, Mäkelä, T, Hillamo, R, Mihalopoulos, N. 2008. Chemical composition and sources of fine and coarse aerosol particles in the Eastern Mediterranean. Atmospheric Environment 42(26):65426550.CrossRefGoogle Scholar
Kouvarakis, G, Vrekoussis, M, Mihalopoulos, Ν, Kourtidis, K, Rappengluck, B, Gerasopoulos, E, Zerefos, C. 2002. Spatial and temporal variability of tropospheric ozone (O3) in the boundary layer above the Aegean Sea (Eastern Mediterranean). Journal of Geophysical Research: Atmospheres 107:8137.CrossRefGoogle Scholar
Lelieveld, J, Berresheim, H, Borrmann, S, Crutzen, PJ, Dentener, FJ, Fischer, H, Feichter, J, Flatau, PJ, Heland, J, Holzinger, R et al. 2002. Global air pollution crossroads over the mediterranean. Science 298(5594):794799.CrossRefGoogle Scholar
Li, C, Zhang, C, Yan, F, Kang, S, Xu, Y, Liu, Y, Gao, Y, Chen, P, He, C. 2022. Importance of local non-fossil sources to carbonaceous aerosols at the eastern fringe of the tibetan plateau, china: Delta(14)c and delta(13)c evidences. Environ Pollut. 311:119858.CrossRefGoogle Scholar
Lim, S, Hwang, J, Lee, M, Czimczik, CI, Xu, X, Savarino, J. 2022. Robust evidence of (14)C, (13)C, and (15)N analyses indicating fossil fuel sources for total carbon and ammonium in fine aerosols in seoul megacity. Environ Sci Technol. 56(11):68946904.CrossRefGoogle Scholar
Lin, YH, Arashiro, M, Clapp, PW, Cui, T, Sexton, KG, Vizuete, W, Gold, A, Jaspers, I, Fry, RC, Surratt, JD. 2017. Gene expression profiling in human lung cells exposed to isoprene-derived secondary organic aerosol. Environ Sci Technol. 51(14):81668175.CrossRefGoogle ScholarPubMed
Liu, JW, Mo, YZ, Li, J, Liu, D, Shen, CD, Ding, P, Jiang, HY, Cheng, ZN, Zhang, XY, Tian, CG et al. 2016. Radiocarbon-derived source apportionment of fine carbonaceous aerosols before, during, and after the 2014 Asia-Pacific Economic Cooperation (APEC) summit in Beijing, China. J Geophys Res-Atmos. 121(8):41774187.CrossRefGoogle Scholar
Loo, BW, Cork, CP. 1988. Development of high efficiency virtual impactors. Aerosol Science and Technology 9(3):167176.CrossRefGoogle Scholar
Menon, S, Hansen, J, Nazarenko, L, Luo, Y. 2002. Climate effects of black carbon aerosols in china and india. Science 297(5590):22502253.CrossRefGoogle ScholarPubMed
Miyazaki, Y, Kawamura, K, Jung, J, Furutani, H, Uematsu, M. 2011. Latitudinal distributions of organic nitrogen and organic carbon in marine aerosols over the western North Pacific. Atmospheric Chemistry and Physics 11, 30373049. doi: 10.5194/acp-11-3037-2011.CrossRefGoogle Scholar
Narukawa, M, Kawamura, K, Li, SM, Bottenheim, JW. 2008. Stable carbon isotopic ratios and ionic composition of the high-arctic aerosols: An increase in δ13C values from winter to spring. Journal of Geophysical Research 113(D2).CrossRefGoogle Scholar
Nel, A. 2005. Air pollution–related illness: effects of particles. Science 308:804806.CrossRefGoogle ScholarPubMed
Novakov, T, Penner, JE. 1993. Large contribution of organic aerosols to cloud-condensation-nuclei concentrations. Nature 365(6449):823826.CrossRefGoogle Scholar
Paraskevopoulou, D, Liakakou, E, Gerasopoulos, E, Theodosi, C, Mihalopoulos, N. 2014. Long-Term characterization of organic and elemental carbon in the PM2.5 fraction: the case of Athens, Greece. Atmospheric Chemistry and Physics 14(23):1331313325.CrossRefGoogle Scholar
Pavuluri, CM, Kawamura, K, Aggarwal, SG, Swaminathan, T. 2011a. Characteristics, seasonality and sources of carbonaceous and ionic components in the tropical aerosols from indian region. Atmospheric Chemistry and Physics 11(15):82158230.CrossRefGoogle Scholar
Pavuluri, CM, Kawamura, K, Swaminathan, T, Tachibana, E. 2011b. Stable carbon isotopic compositions of total carbon, dicarboxylic acids and glyoxylic acid in the tropical indian aerosols: Implications for sources and photochemical processing of organic aerosols. Journal of Geophysical Research 116(D18).CrossRefGoogle Scholar
Pavuluri, CM, Kawamura, K, Uchida, M, Kondo, M, Fu, P. 2013. Enhanced modern carbon and biogenic organic tracers in northeast asian aerosols during spring/summer. Journal of Geophysical Research: Atmospheres 118(5):23622371.CrossRefGoogle Scholar
Ramanathan, V, Crutzen, PJ, Kiehl, JT, Rosenfeld, D. 2001. Atmosphere—aerosols, climate, and the hydrological cycle. Science 294(5549):21192124.CrossRefGoogle Scholar
Robinson, AL, Donahue, NM, Shrivastava, MK, Weitkamp, EA, Sage, AM, Grieshop, AP, Lane, TE, Pierce, JR, Pandis, SN. 2007. Rethinking organic aerosols: semivolatile emissions and photochemical aging. Science 315(5816):12591262.CrossRefGoogle ScholarPubMed
Rosenfeld, D, Zhu, Y, Wang, M, Zheng, Y, Goren, T, Yu, S. 2019. Aerosol-driven droplet concentrations dominate coverage and water of oceanic low-level clouds. Science 363(6427):eaav0566. doi: 10.1126/science.aav0566.CrossRefGoogle ScholarPubMed
Rudolph, J. 2002. Stable carbon isotope ratio measurements: A new tool to understand atmospheric processing of volatile organic compounds. Nato Sci S Ss Iv Ear. 16:3742.Google Scholar
Sciare, J, Bardouki, H, Moulin, C, Mihalopoulos, N. 2003. Aerosol sources and their contribution to the chemical composition of aerosols in the eastern mediterranean sea during summertime. Atmospheric Chemistry and Physics 3:291302.CrossRefGoogle Scholar
Sciare, J, Oikonomou, K, Favez, O, Liakakou, E, Markaki, Z, Cachier, H, Mihalopoulos, N. 2008. Long-term measurements of carbonaceous aerosols in the eastern mediterranean: Evidence of long-range transport of biomass burning. Atmospheric Chemistry and Physics 8(18):55515563.CrossRefGoogle Scholar
Simoneit, BRT, Kobayashi, M, Mochida, M, Kawamura, K, Lee, M, Lim, HJ, Turpin, BJ, Komazaki, Y. 2004. Composition and major sources of organic compounds of aerosol particulate matter sampled during the ace-asia campaign. J Geophys Res-Atmos. 109:D19S10. doi: 10.1029/2004JD004598.Google Scholar
Song, J, Zhu, M, Wei, S, Peng Pa, Ren M. 2019. Abundance and 14C-based source assessment of carbonaceous materials in pm2.5 aerosols in Guangzhou, South China. Atmospheric Pollution Research 10(1):313320.CrossRefGoogle Scholar
Srivastava, D, Vu, TV, Tong, S, Shi, Z, Harrison, RM. 2022. Formation of secondary organic aerosols from anthropogenic precursors in laboratory studies. NPJ Climate and Atmospheric Science 5:22. doi: 10.1038/s41612-022-00238-6.CrossRefGoogle Scholar
Stock, M, Cheng, YF, Birmili, W, Massling, A, Wehner, B, Müller, T, Leinert, S, Kalivitis, N, Mihalopoulos, N, Wiedensohler, A. 2011. Hygroscopic properties of atmospheric aerosol particles over the Eastern Mediterranean: implications for regional direct radiative forcing under clean and polluted conditions. Atmospheric Chemistry and Physics 11(9):42514271.CrossRefGoogle Scholar
Stuiver, M, Polach, H. 1977. Discussion: reporting of 14C data. Radiocarbon 19(3):355363.CrossRefGoogle Scholar
Szidat, S, Jenk, TM, Gäggeler, HW, Synal, HA, Fisseha, R, Baltensperger, U, Kalberer, M, Samburova, V, Reimann, S, Kasper-Giebl, A et al. 2004. Radiocarbon (14C)-deduced biogenic and anthropogenic contributions to organic carbon (OC) of urban aerosols from zürich, switzerland. Atmospheric Environment 38(24):40354044.CrossRefGoogle Scholar
Theodosi, C, Panagiotopoulos, C, Nouara, A, Zarmpas, P, Nicolaou, P, Violaki, K, Kanakidou, M, Sempere, R, Mihalopoulos, N. 2018. Sugars in atmospheric aerosols over the Eastern Mediterranean. Progress in Oceanography, 163:7081.CrossRefGoogle Scholar
Turekian, VC. 2003. Concentrations, isotopic compositions, and sources of size-resolved, particulate organic carbon and oxalate in near-surface marine air at Bermuda during spring. Journal of Geophysical Research 108(D5), 4157. doi: 10.1029/2002JD002053.CrossRefGoogle Scholar
Turekian, VC, Macko, S, Ballentine, D, Swap, RJ, Garstang, M. 1998. Causes of bulk carbon and nitrogen isotopic fractionations in the products of vegetation burns: laboratory studies. Chem Geol. 152(1–2):181192.CrossRefGoogle Scholar
Uchida, M, Kumata, H, Koike, Y, Tsuzuki, M, Uchida, T, Fujiwara, K, Shibata, Y. 2010. Radiocarbon-based source apportionment of black carbon (BC) in pm10 aerosols from residential area of suburban Tokyo. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 268(7–8):11201124.CrossRefGoogle Scholar
Uchida, M, Mantoku, K, Kobayashi, T, Kawamura, K, Shibata, Y. 2023. Ultra small mass AMS 14C sample preparation and analyses at NIES-TERRA AMS facility. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 536:144153.CrossRefGoogle Scholar
Uchida, M, Shibata, Y, Yoneda, M, Kobayashi, T, Morita, M. 2004. Technical progress in ams microscale radiocarbon analysis. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 223–224:313317.CrossRefGoogle Scholar
Urdiales-Flores, D, Zittis, G, Hadjinicolaou, P, Osipov, S, Klingmüller, K, Mihalopoulos, N, Kanakidou, M, Economou, T, Lelieveld, J. 2023. Drivers of accelerated warming in mediterranean climate-type regions. NPJ Climate and Atmospheric Science 6:97. doi: 10.1038/s41612-023-00423-1.CrossRefGoogle Scholar
Vrekoussis, M, Liakakou, E, Koçak, M, Kubilay, N, Oikonomou, K, Sciare, J, Mihalopoulos, N. 2005. Seasonal variability of optical properties of aerosols in the Eastern Mediterranean. Atmospheric Environment 39(37):70837094.CrossRefGoogle Scholar
Wang, Y, Pavuluri, CM, Fu, P, Li, P, Dong, Z, Xu, Z, Ren, H, Fan, Y, Li, L, Zhang, Y-L. 2019. Characterization of secondary organic aerosol tracers over Tianjin, North China during summer to autumn. ACS Earth and Space Chemistry 3(10):23392352.CrossRefGoogle Scholar
Widory, D, Roy, S, Moullec, YL, Goupil, G, Cocherie, A, Guerrot, C. 2004. The origin of atmospheric particles in Paris: a view through carbon and lead isotopes. Atmospheric Environment 38:953961.CrossRefGoogle Scholar
Yttri, KE, Simpson, D, Bergström, R, Kiss, G, Szidat, S, Ceburnis, D, Eckhardt, S, Hueglin, C, Nøjgaard, JK, Perrino, C et al. 2019. The emep intensive measurement period campaign, 2008–2009: characterizing carbonaceous aerosol at nine rural sites in Europe. Atmospheric Chemistry and Physics 19(7):42114233.CrossRefGoogle Scholar
Figure 0

Table 1 Annual and seasonal summary of the concentrations of carbonaceous components and PM1.3 (μgm−3), δ13CTC (‰) and 14CTC (pMC) in the PM1.3 from Finokalia, Crete Island, Greece, the Eastern Mediterranean during October 2009–October 2010. See text for abbreviations.

Figure 1

Figure 1 Temporal variations in concentrations of (a) EC, CC and WIOC, (b) WSOC and SOC, (c) OC and TC in PM1.3 and (d) PM1.3 mass, (e) δ13CTC and (f) 14CTC (pMC) in the PM1.3 from Finokalia, Crete Island, Greece, the Eastern Mediterranean during October 2009–October 2010. See text for abbreviations.

Figure 2

Figure 2 (a) Scatter plot between the concentrations of TC (μg m−3) and its 14CTC (pMC) and seasonal changes in average concentrations (bars, μg m−3, error bars show the standard deviation) of fossil (FCTC) and non-fossil carbon (NFCTC) contents in TC in PM1.3 from Finokalia, Crete Island, Greece, the eastern Mediterranean.

Figure 3

Figure 3 Total concentrations (ng m−3) of biomarker species: fatty acids (∑C8-C32), levoglucosan, isoprene- (∑2-methylglyceric acid+cis-2-methyl-1,3,4-trihydroxy-1-butene+3-methyl-2,3,4-trihydroxy-1-butene+trans-2-methyl-1,3,4-trihydroxy-1-butene+2-methylthreitol+2-methylerythritol) and α-pinene-derived SOA (∑3-hydroxyglutaric acid+pinonic acid+pinic acid+3-methyl-1,2,3-butanetricarboxylic acid) species, and β-caryophyllinic acid, sucrose and mannitol in PM1.3 from Finokalia, Crete Island, Greece, the eastern Mediterranean in autumn (a), winter (b), spring (c) and summer (d).