Detailed Carbon Isotope Study of PM2.5 Aerosols at Urban Background, Suburban Background and Regional Background Sites in Hungary

Major, István; Molnár, Mihály; Futó, István; Gergely, Virág; Bán, Sándor; Machon, Attila; Salma, Imre; Varga, Tamás

doi:10.3390/atmos13050716

Cited by 4 publications

(1 citation statement)

References 53 publications

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“…Note also from Table 3 that a very high contribution of modern carbon f c , likely associated with a larger biomass burning contribution, was observed only in 2 samples (W1 and W6). The values of f c reported in this study resulted slightly higher than those found by Major et al (2022) who analyzed PM2.5 samples in different urban background, suburban background, and rural sites in Budapest (Hungary). In more detail, they found seasonal mean f c values between 50 and 78% suggesting that modern sources were significant during the observation year, regardless of the heating or vegetation periods.…”

Section: Samplecontrasting

confidence: 88%

Characterization of the PM2.5 aerosol fraction monitored at a suburban site in south-eastern Italy by integrating isotopic techniques and ion beam analysis

Romano

Pichierri

Fragola

et al. 2022

Front. Environ. Sci.

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Both teflon and quartz PM2.5 filters collected from January to July 2021 at the monitoring site of the Department of Mathematics and Physics of the University of Salento in Lecce (Italy) were analyzed by integrating different characterization techniques (Particle Induced X-ray Emission PIXE, Isotope Ratio Mass Spectrometry IRMS, and Accelerator Mass Spectrometry AMS) at the CEDAD (Center of Applied Physics, Dating and Diagnostics) of the Department of Mathematics and Physics, University of Salento. The PM2.5 concentration analyses allowed to identify the variation of the main PM2.5 characteristics as a function of the season and the day of the week. This last characterization was integrated by the results from the PIXE, which allowed to identify the heavy elements and their concentrations. The main results showed the presence of different elements, such as S and Zn (considered as markers of anthropogenic sources for PM2.5) and Ca and Fe (as markers of natural sources). The concentrations of these elements showed a significant decrease during the weekend, mostly in the case of elements of anthropogenic origin, according to the data on the PM2.5 temporal evolution. Using the isotopic markers of carbon and nitrogen by means of the IRMS, we determined values of δ15N between 4.5 and 10.6‰, which are consistent with the origin of PM2.5 from anthropic combustion processes and a secondary contribution from vehicular traffic. Similarly, the values of δ13C obtained by IRMS were in the range between −24.4 and −26.7‰, generally associated with biomass combustion and with vehicular traffic. An analysis of the fossil and modern contribution was carried out on the PM2.5 filters by measuring radiocarbon using the integrated IRMS-EA system connected with the TANDETRON accelerator and AMS spectrometer. In more detail, we found a percentage of modern carbon in the range 71.6–92.4% that indicates a larger bio-derived contribution with respect to the contribution from fossil sources during the analyzed period. The parameters obtained from PIXE, IRMS, and AMS techniques were finally used as input for different ordination methods that allowed their deeper characterization.

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Section: Samplecontrasting

confidence: 88%