Your search keyword '"T. Piansawan"' showing total 2 results

1. Firewood residential heating – local versus remote influence on the aerosol burden

Author

C. Betancourt, C. Küppers, T. Piansawan, U. Sager, A. B. Hoyer, H. Kaminski, G. Rapp, A. C. John, M. Küpper, U. Quass, T. Kuhlbusch, J. Rudolph, A. Kiendler-Scharr, and I. Gensch

Subjects

Physics, QC1-999, Chemistry, QD1-999

Abstract

We report the first-time use of the Lagrangian particle dispersion model (LPDM) FLEXPART to simulate isotope ratios of the biomass burning tracer levoglucosan. Here, we combine the model results with observed levoglucosan concentrations and δ13C to assess the contribution of local vs. remote emissions from firewood domestic heating to the particulate matter sampled during the cold season at two measurements stations of the Environmental Agency of North Rhine-Westphalia, Germany. For the investigated samples, the simulations indicate that the largest part of the sampled aerosol is 1 to 2 d old and thus originates from local to regional sources. Consequently, ageing, also limited by the reduced photochemical activity in the dark cold season, has a minor influence on the observed levoglucosan concentration and δ13C. The retro plume ages agree well with those derived from observed δ13C (the “isotopic” ages), demonstrating that the limitation of backwards calculations to 7 d for this study does not introduce any significant bias. A linear regression analysis applied to the experimental levoglucosan δ13C vs. the inverse concentration confirms the young age of aerosol. The high variability in the observed δ13C implies that the local levoglucosan emissions are characterized by different isotopic ratios in the range of −26.3 ‰ to −21.3 ‰. These values are in good agreement with previous studies on levoglucosan source-specific isotopic composition in biomass burning aerosol. Comparison between measured and estimated levoglucosan concentrations suggests that emissions are underestimated by a factor of 2 on average. These findings demonstrate that the aerosol burden from home heating in residential areas is not of remote origin. In this work we show that combining Lagrangian modelling with isotope ratios is valuable to obtain additional insight into source apportionment. Error analysis shows that the largest source of uncertainty is limited information on isotope ratios of levoglucosan emissions. Based on the observed low extent of photochemical processing during the cold season, levoglucosan can be used under similar conditions as a conservative tracer without introducing substantial bias.

Published

2021

2. Temperature dependence of stable carbon kinetic isotope effect for the oxidation reaction of ethane by OH radicals: Experimental and theoretical studies

Author

Luc Vereecken, Iulia Gensch, T. Piansawan, Astrid Kiendler-Scharr, and M. Saccon

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Isotope, Chemistry, Analytical chemistry, Natural abundance, Atmospheric temperature range, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Reaction rate, Transition state theory, Geophysics, Isotope fractionation, Space and Planetary Science, Kinetic isotope effect, Earth and Planetary Sciences (miscellaneous), Isotopologue, 0105 earth and related environmental sciences

Abstract

The stable carbon kinetic isotope effect (KIE) of ethane photo-oxidation by OH radicals was deduced by employing both laboratory measurements and theoretical calculations. The investigations were designed to elucidate the temperature dependence of KIE within atmospherically relevant temperature range. The experimental KIE were derived from laboratory compound specific isotope analyses of ethane with natural isotopic abundance exposed to OH at constant temperature, showing e values of 7.16 ± 0.54 ‰ (303 K), 7.45 ± 0.48 ‰ (288 K), 7.36 ± 0.28 ‰ (273 K), 7.61 ± 0.28 ‰ (263 K), 8.89 ± 0.90‰ (253 K), and 9.42 ± 2.19% (243 K). Compared to previous studies, a significant improvement of the measurement precision was reached at the high end of the investigated temperature range. The KIE was theoretically determined as well, in the temperature range of 150 K to 400 K, by calculating the reaction rate coefficients of 12C and singly 13C substituted ethane isotopologues applying chemical quantum mechanics together with transition state theory. Tunneling effect and internal rotations were also considered. The agreement between experimental and theoretical results for rate coefficients and KIE in an atmospherically relevant temperature range is discussed. However, both laboratory observations and computational predictions show no significant temperature dependence of the KIE for the ethane oxidation by OH radicals.

Published

2017