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2. Comparison of isoprene chemical mechanisms under atmospheric night-time conditions in chamber experiments: evidence of hydroperoxy aldehydes and epoxy products from NO3 oxidation

Author

Carlsson, Philip T. M., Vereecken, Luc, Novelli, Anna, Bernard, François, Brown, Steven S., Brownwood, Bellamy, Cho, Changmin, Crowley, John N., Dewald, Patrick, Edwards, Peter M., Friedrich, Nils, Fry, Juliane L., Hallquist, Mattias, Hantschke, Luisa, Hohaus, Thorsten, Kang, Sungah, Liebmann, Jonathan, Mayhew, Alfred W., Mentel, Thomas, Reimer, David, Rohrer, Franz, Shenolikar, Justin, Tillmann, Ralf, Tsiligiannis, Epameinondas, Wu, Rongrong, Wahner, Andreas, Kiendler-Scharr, Astrid, and Fuchs, Hendrik

Subjects
Atmospheric Science, ddc:550, Life Science
Abstract

The gas-phase reaction of isoprene with the nitrate radical (NO3) was investigated in experiments in the outdoor SAPHIR chamber under atmospherically relevant conditions specifically with respect to the chemical lifetime and fate of nitrato-organic peroxy radicals (RO2). Observations of organic products were compared to concentrations expected from different chemical mechanisms: (1) the Master Chemical Mechanism, which simplifies the NO3 isoprene chemistry by only considering one RO2 isomer; (2) the chemical mechanism derived from experiments in the Caltech chamber, which considers different RO2 isomers; and (3) the FZJ-NO3 isoprene mechanism derived from quantum chemical calculations, which in addition to the Caltech mechanism includes equilibrium reactions of RO2 isomers, unimolecular reactions of nitrate RO2 radicals and epoxidation reactions of nitrate alkoxy radicals. Measurements using mass spectrometer instruments give evidence that the new reactions pathways predicted by quantum chemical calculations play a role in the NO3 oxidation of isoprene. Hydroperoxy aldehyde (HPALD) species, which are specific to unimolecular reactions of nitrate RO2, were detected even in the presence of an OH scavenger, excluding the possibility that concurrent oxidation by hydroxyl radicals (OH) is responsible for their formation. In addition, ion signals at masses that can be attributed to epoxy compounds, which are specific to the epoxidation reaction of nitrate alkoxy radicals, were detected. Measurements of methyl vinyl ketone (MVK) and methacrolein (MACR) concentrations confirm that the decomposition of nitrate alkoxy radicals implemented in the Caltech mechanism cannot compete with the ring-closure reactions predicted by quantum chemical calculations. The validity of the FZJ-NO3 isoprene mechanism is further supported by a good agreement between measured and simulated hydroxyl radical (OH) reactivity. Nevertheless, the FZJ-NO3 isoprene mechanism needs further investigations with respect to the absolute importance of unimolecular reactions of nitrate RO2 and epoxidation reactions of nitrate alkoxy radicals. Absolute concentrations of specific organic nitrates such as nitrate hydroperoxides would be required to experimentally determine product yields and branching ratios of reactions but could not be measured in the chamber experiments due to the lack of calibration standards for these compounds. The temporal evolution of mass traces attributed to product species such as nitrate hydroperoxides, nitrate carbonyl and nitrate alcohols as well as hydroperoxy aldehydes observed by the mass spectrometer instruments demonstrates that further oxidation by the nitrate radical and ozone at atmospheric concentrations is small on the timescale of one night (12 h) for typical oxidant concentrations. However, oxidation by hydroxyl radicals present at night and potentially also produced from the decomposition of nitrate alkoxy radicals can contribute to their nocturnal chemical loss.

Published
2023
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3. Impact of HO2/RO2 ratio on highly oxygenated α-pinene photooxidation products and secondary organic aerosol formation potential.

Author

Baker, Yarê, Kang, Sungah, Wang, Hui, Wu, Rongrong, Xu, Jian, Zanders, Annika, He, Quanfu, Hohaus, Thorsten, Ziehm, Till, Geretti, Veronica, Bannan, Thomas J., O'Meara, Simon P., Voliotis, Aristeidis, Hallquist, Mattias, McFiggans, Gordon, Zorn, Sören R., Wahner, Andreas, and Mentel, Thomas F.

Subjects
PINENE, ORGANIC products, AEROSOLS, HYDROGEN peroxide, PEROXY radicals, PHOTOOXIDATION
Abstract

Highly oxygenated molecules (HOMs) from the atmospheric oxidation of biogenic volatile organic compounds are important contributors to secondary organic aerosol (SOA). Organic peroxy radicals (RO 2) and hydroperoxy radicals (HO 2) are key species influencing the HOM product distribution. In laboratory studies, experimental requirements often result in overemphasis on RO 2 cross-reactions compared to reactions of RO 2 with HO 2. We analyzed the photochemical formation of HOMs from α -pinene and their potential to contribute to SOA formation under high (≈1 /1) and low (≈1 /100) HO2/RO2 conditions. As HO2/RO2 > 1 is prevalent in the daytime atmosphere, sufficiently high HO2/RO2 is crucial to mimic atmospheric conditions and to prevent biases by low HO2/RO2 on the HOM product distribution and thus SOA yield. Experiments were performed under steady-state conditions in the new, continuously stirred tank reactor SAPHIR-STAR at Forschungszentrum Jülich. The HO2/RO2 ratio was increased by adding CO while keeping the OH concentration constant. We determined the HOM's SOA formation potential, considering its fraction remaining in the gas phase after seeding with (NH 4)2 SO 4 aerosol. An increase in HO2/RO2 led to a reduction in SOA formation potential, with the main driver being a ∼ 60 % reduction in HOM-accretion products. We also observed a shift in HOM-monomer functionalization from carbonyl to hydroperoxide groups. We determined a reduction of the HOM's SOA formation potential by ∼ 30 % at HO2/RO2 ≈1 /1 compared to HO2/RO2 ≈ 1/100. Particle-phase observations measured a similar decrease in SOA mass and yield. Our study shows that too low HO2/RO2 ratios compared to the atmosphere can lead to an overestimation of SOA yields. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Secondary organic aerosol reduced by mixture of atmospheric vapours

Author

McFiggans, Gordon, Mentel, Thomas F., Wildt, Jürgen, Pullinen, Iida, Kang, Sungah, Kleist, Einhard, Schmitt, Sebastian, Springer, Monika, Tillmann, Ralf, Wu, Cheng, Zhao, Defeng, Hallquist, Mattias, Faxon, Cameron, Le Breton, Michael, Hallquist, Åsa M., Simpson, David, Bergström, Robert, Jenkin, Michael E., Ehn, Mikael, Thornton, Joel A., Alfarra, M. Rami, Bannan, Thomas J., Percival, Carl J., Priestley, Michael, Topping, David, and Kiendler-Scharr, Astrid

Published
2019
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5. Comparison of isoprene chemical mechanisms under atmospheric night-time conditions in chamber experiments : Evidence of hydroperoxy aldehydes and epoxy products from NO3 oxidation

Author

Carlsson, Philip T.M., Vereecken, Luc, Novelli, Anna, Bernard, François, Brown, Steven S., Brownwood, Bellamy, Cho, Changmin, Crowley, John N., Dewald, Patrick, Edwards, Peter M., Friedrich, Nils, Fry, Juliane L., Hallquist, Mattias, Hantschke, Luisa, Hohaus, Thorsten, Kang, Sungah, Liebmann, Jonathan, Mayhew, Alfred W., Mentel, Thomas, Reimer, David, Rohrer, Franz, Shenolikar, Justin, Tillmann, Ralf, Tsiligiannis, Epameinondas, Wu, Rongrong, Wahner, Andreas, Kiendler-Scharr, Astrid, Fuchs, Hendrik, Carlsson, Philip T.M., Vereecken, Luc, Novelli, Anna, Bernard, François, Brown, Steven S., Brownwood, Bellamy, Cho, Changmin, Crowley, John N., Dewald, Patrick, Edwards, Peter M., Friedrich, Nils, Fry, Juliane L., Hallquist, Mattias, Hantschke, Luisa, Hohaus, Thorsten, Kang, Sungah, Liebmann, Jonathan, Mayhew, Alfred W., Mentel, Thomas, Reimer, David, Rohrer, Franz, Shenolikar, Justin, Tillmann, Ralf, Tsiligiannis, Epameinondas, Wu, Rongrong, Wahner, Andreas, Kiendler-Scharr, Astrid, and Fuchs, Hendrik

Abstract

The gas-phase reaction of isoprene with the nitrate radical (NO3) was investigated in experiments in the outdoor SAPHIR chamber under atmospherically relevant conditions specifically with respect to the chemical lifetime and fate of nitrato-organic peroxy radicals (RO2). Observations of organic products were compared to concentrations expected from different chemical mechanisms: (1) the Master Chemical Mechanism, which simplifies the NO3 isoprene chemistry by only considering one RO2 isomer; (2) the chemical mechanism derived from experiments in the Caltech chamber, which considers different RO2 isomers; and (3) the FZJ-NO3 isoprene mechanism derived from quantum chemical calculations, which in addition to the Caltech mechanism includes equilibrium reactions of RO2 isomers, unimolecular reactions of nitrate RO2 radicals and epoxidation reactions of nitrate alkoxy radicals. Measurements using mass spectrometer instruments give evidence that the new reactions pathways predicted by quantum chemical calculations play a role in the NO3 oxidation of isoprene. Hydroperoxy aldehyde (HPALD) species, which are specific to unimolecular reactions of nitrate RO2, were detected even in the presence of an OH scavenger, excluding the possibility that concurrent oxidation by hydroxyl radicals (OH) is responsible for their formation. In addition, ion signals at masses that can be attributed to epoxy compounds, which are specific to the epoxidation reaction of nitrate alkoxy radicals, were detected. Measurements of methyl vinyl ketone (MVK) and methacrolein (MACR) concentrations confirm that the decomposition of nitrate alkoxy radicals implemented in the Caltech mechanism cannot compete with the ring-closure reactions predicted by quantum chemical calculations. The validity of the FZJ-NO3 isoprene mechanism is further supported by a good agreement between measured and simulated hydroxyl radical (OH) reactivity. Nevertheless, the FZJ-NO3 isoprene mechanism needs further investigations

Published
2023

7. Identification of highly oxygenated organic molecules and their role in aerosol formation in the reaction of limonene with nitrate radical

Author

Guo, Yindong, primary, Shen, Hongru, additional, Pullinen, Iida, additional, Luo, Hao, additional, Kang, Sungah, additional, Vereecken, Luc, additional, Fuchs, Hendrik, additional, Hallquist, Mattias, additional, Acir, Ismail-Hakki, additional, Tillmann, Ralf, additional, Rohrer, Franz, additional, Wildt, Jürgen, additional, Kiendler-Scharr, Astrid, additional, Wahner, Andreas, additional, Zhao, Defeng, additional, and Mentel, Thomas F., additional

Published
2022
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8. Formation of highly oxygenated organic molecules from the oxidation of limonene by OH radical: significant contribution of H-abstraction pathway.

Author

Luo, Hao, Vereecken, Luc, Shen, Hongru, Kang, Sungah, Pullinen, Iida, Hallquist, Mattias, Fuchs, Hendrik, Wahner, Andreas, Kiendler-Scharr, Astrid, Mentel, Thomas F., and Zhao, Defeng

Subjects
LIMONENE, RADICALS (Chemistry), PEROXY radicals, CHEMICAL ionization mass spectrometry, MOLECULES, STRUCTURE-activity relationships, NITRATE reductase
Abstract

Highly oxygenated organic molecules (HOMs) play a pivotal role in the formation of secondary organic aerosol (SOA). Therefore, the distribution and yields of HOMs are fundamental to understand their fate and chemical evolution in the atmosphere, and it is conducive to ultimately assess the impact of SOA on air quality and climate change. In this study, gas-phase HOMs formed from the reaction of limonene with OH radicals in photooxidation were investigated with SAPHIR (Simulation of Atmospheric PHotochemistry In a large Reaction chamber), using a time-of-flight chemical ionization mass spectrometer with nitrate reagent ion (NO 3- -CIMS). A large number of HOMs, including monomers (C 9–10) and dimers (C 17–20), were detected and classified into various families. Both closed-shell products and open-shell peroxy radicals (RO 2) were identified under low NO (0.06–0.1 ppb) and high NO conditions (17 ppb). C 10 monomers are the most abundant HOM products and account for over 80 % total HOMs. Closed-shell C 10 monomers were formed from a two peroxy radical family, C 10 H 15 O x⚫ (x=6 –15) and C 10 H 17 O x⚫ (x=6 –15), and their respective termination reactions with NO, RO 2 , and HO 2. While C 10 H 17 O x⚫ is likely formed by OH addition to C 10 H 16 , the dominant initial step of limonene plus OH, C 10 H 15 O x⚫ , is likely formed via H abstraction by OH. C 10 H 15 O x⚫ and related products contributed 41 % and 42 % of C 10 HOMs at low and high NO, demonstrating that the H-abstraction pathways play a significant role in HOM formation in the reaction of limonene plus OH. Combining theoretical kinetic calculations, structure–activity relationships (SARs), data from the literature, and the observed RO 2 intensities, we proposed tentative mechanisms of HOM formation from both pathways. We further estimated the molar yields of HOMs to be 1.97-1.06+2.52 % and 0.29-0.16+0.38 % at low and high NO, respectively. Our study highlights the importance of H abstraction by OH and provides the yield and tentative pathways in the OH oxidation of limonene to simulate the HOM formation and assess the role of HOMs in SOA formation. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Unexpected significance of a minor reaction pathway in daytime formation of biogenic highly oxygenated organic compounds

Author

Shen, Hongru, Vereecken, Luc, Kang, Sungah, Pullinen, Iida, Fuchs, Hendrik, Zhao, Defeng, Mentel, Thomas F., Shen, Hongru, Vereecken, Luc, Kang, Sungah, Pullinen, Iida, Fuchs, Hendrik, Zhao, Defeng, and Mentel, Thomas F.

Abstract

Secondary organic aerosol (SOA), formed by oxidation of volatile organic compounds, substantially influence air quality and climate. Highly oxygenated organic molecules (HOMs), particularly those formed from biogenic monoterpenes, contribute a large fraction of SOA. During daytime, hydroxyl radicals initiate monoterpene oxidation, mainly by hydroxyl addition to monoterpene double bonds. Naturally, related HOM formation mechanisms should be induced by that reaction route, too. However, for a-pinene, the most abundant atmospheric monoterpene, we find a previously unidentified competitive pathway under atmospherically relevant conditions: HOM formation is predominately induced via hydrogen abstraction by hydroxyl radicals, a generally minor reaction pathway. We show by observations and theoretical calculations that hydrogen abstraction followed by formation and rearrangement of alkoxy radicals is a prerequisite for fast daytime HOM formation. Our analysis provides an accurate mechanism and yield, demonstrating that minor reaction pathways can become major, here for SOA formation and growth and related impacts on air quality and climate.

Published
2022

10. A Four Carbon Organonitrate as a Significant Product of Secondary Isoprene Chemistry

Author

Tsiligiannis, Epameinondas, Wu, Rongrong, Lee, Ben H., Salvador, Christian Mark, Priestley, Michael, Carlsson, Philip T.M., Kang, Sungah, Novelli, Anna, Vereecken, Luc, Fuchs, Hendrik, Mayhew, Alfred W., Hamilton, Jacqueline F., Edwards, Peter M., Fry, Juliane L., Brownwood, Bellamy, Brown, Steven S., Wild, Robert J., Bannan, Thomas J., Coe, Hugh, Allan, James, Surratt, Jason D., Bacak, Asan, Artaxo, Paul, Percival, Carl, Guo, Song, Hu, Min, Wang, Tao, Mentel, Thomas F., Thornton, Joel A., Hallquist, Mattias, Tsiligiannis, Epameinondas, Wu, Rongrong, Lee, Ben H., Salvador, Christian Mark, Priestley, Michael, Carlsson, Philip T.M., Kang, Sungah, Novelli, Anna, Vereecken, Luc, Fuchs, Hendrik, Mayhew, Alfred W., Hamilton, Jacqueline F., Edwards, Peter M., Fry, Juliane L., Brownwood, Bellamy, Brown, Steven S., Wild, Robert J., Bannan, Thomas J., Coe, Hugh, Allan, James, Surratt, Jason D., Bacak, Asan, Artaxo, Paul, Percival, Carl, Guo, Song, Hu, Min, Wang, Tao, Mentel, Thomas F., Thornton, Joel A., and Hallquist, Mattias

Abstract

Oxidation of isoprene by nitrate radicals (NO3) or by hydroxyl radicals (OH) under high NOx conditions forms a substantial amount of organonitrates (ONs). ONs impact NOx concentrations and consequently ozone formation while also contributing to secondary organic aerosol. Here we show that the ONs with the chemical formula C4H7NO5 are a significant fraction of isoprene-derived ONs, based on chamber experiments and ambient measurements from different sites around the globe. From chamber experiments we found that C4H7NO5 isomers contribute 5%–17% of all measured ONs formed during nighttime and constitute more than 40% of the measured ONs after further daytime oxidation. In ambient measurements C4H7NO5 isomers usually dominate both nighttime and daytime, implying a long residence time compared to C5 ONs which are removed more rapidly. We propose potential nighttime sources and secondary formation pathways, and test them using a box model with an updated isoprene oxidation scheme.

Published
2022

11. A Four Carbon Organonitrate as a Significant Product of Secondary Isoprene Chemistry

Author

Tsiligiannis, Epameinondas, primary, Wu, Rongrong, additional, Lee, Ben H., additional, Salvador, Christian Mark, additional, Priestley, Michael, additional, Carlsson, Philip T. M., additional, Kang, Sungah, additional, Novelli, Anna, additional, Vereecken, Luc, additional, Fuchs, Hendrik, additional, Mayhew, Alfred W., additional, Hamilton, Jacqueline F., additional, Edwards, Peter M., additional, Fry, Juliane L., additional, Brownwood, Bellamy, additional, Brown, Steven S., additional, Wild, Robert J., additional, Bannan, Thomas J., additional, Coe, Hugh, additional, Allan, James, additional, Surratt, Jason D., additional, Bacak, Asan, additional, Artaxo, Paul, additional, Percival, Carl, additional, Guo, Song, additional, Hu, Min, additional, Wang, Tao, additional, Mentel, Thomas F., additional, Thornton, Joel A., additional, and Hallquist, Mattias, additional

Published
2022
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12. Highly oxygenated organic molecule (HOM) formation in the isoprene oxidation by NO3 radical

Author

Zhao, Defeng, Pullinen, Iida, Kiendler-Scharr, Astrid, Wahner, Andreas, Kang, Sungah, Vereecken, Luc, Mentel, Thomas F., Fuchs, Hendrik, Schrade, Stephanie, Wu, Rongrong, Acir, Ismail-Hakki, Tillmann, Ralf, Rohrer, Franz, Wildt, Jürgen, and Guo, Yindong

Subjects
ddc:550
Abstract

Highly oxygenated organic molecules (HOM) are found to play an important role in the formation and growth of secondary organic aerosol (SOA). SOA is an important type of aerosol with significant impact on air quality and climate. Compared with the oxidation of volatile organic compounds by ozone (O3) and hydroxyl radical (OH), HOM formation in the oxidation by nitrate radical (NO3), an important oxidant at nighttime and dawn, has received less attention. In this study, HOM formation in the reaction of isoprene with NO3 was investigated in the SAPHIR chamber (Simulation of Atmospheric PHotochemistry In a large Reaction chamber). A large number of HOM, including monomers (C5), dimers (C10), and trimers (C15), both closed-shell compounds and open-shell peroxy radicals (RO2), were identified and were classified into various series according to their formula. Their formation pathways were proposed based on the peroxy radicals observed and known mechanisms in the literature, which were further constrained by the time profiles of HOM after sequential isoprene addition to differentiate first- and second-generation products. HOM monomers containing one to three N atoms (1–3N-monomers) were formed, starting with NO3 addition to carbon double bond, forming peroxy radicals, followed by autoxidation. 1N-monomers were formed by both the direct reaction of NO3 with isoprene and of NO3 with first-generation products. 2N-monomers (e.g., C5H8N2On(n=7–13), C5H10N2On(n=8–14)) were likely the termination products of C5H9N2On⚫, which was formed by the addition of NO3 to C5-hydroxynitrate (C5H9NO4), a first-generation product containing one carbon double bond. 2N-monomers, which were second-generation products, dominated in monomers and accounted for ∼34 % of all HOM, indicating the important role of second-generation oxidation in HOM formation in the isoprene + NO3 reaction under our experimental conditions. H shift of alkoxy radicals to form peroxy radicals and subsequent autoxidation (“alkoxy–peroxy” pathway) was found to be an important pathway of HOM formation. HOM dimers were mostly formed by the accretion reaction of various HOM monomer RO2 and via the termination reactions of dimer RO2 formed by further reaction of closed-shell dimers with NO3 and possibly by the reaction of C5–RO2 with isoprene. HOM trimers were likely formed by the accretion reaction of dimer RO2 with monomer RO2. The concentrations of different HOM showed distinct time profiles during the reaction, which was linked to their formation pathway. HOM concentrations either showed a typical time profile of first-generation products, second-generation products, or a combination of both, indicating multiple formation pathways and/or multiple isomers. Total HOM molar yield was estimated to be 1.2 %-0.7%+1.3%, which corresponded to a SOA yield of ∼3.6 % assuming the molecular weight of C5H9NO6 as the lower limit. This yield suggests that HOM may contribute a significant fraction to SOA yield in the reaction of isoprene with NO3.

Published
2021
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13. Chemical characterisation of benzene oxidation products under high- And low-NOx conditions using chemical ionisation mass spectrometry

Author

Priestley, Michael, Bannan, Thomas J., Breton, Michael, Worrall, Stephen D., Kang, Sungah, Pullinen, Iida, Schmitt, Sebastian, Tillmann, Ralf, Kleist, Einhard, Zhao, Defeng, Wildt, Jürgen, Garmash, Olga, Mehra, Archit, Bacak, Asan, Shallcross, Dudley E., Kiendler-Scharr, Astrid, Hallquist, Åsa M., Ehn, Mikael, Coe, Hugh, Percival, Carl J., Hallquist, Mattias, Mentel, Thomas F., McFiggans, Gordon, INAR Physics, and Institute for Atmospheric and Earth System Research (INAR)

Subjects
ddc:550, 114 Physical sciences
Abstract

Aromatic hydrocarbons are a class of volatile organic compounds associated with anthropogenic activity and make up a significant fraction of urban volatile organic compound (VOC) emissions that contribute to the formation of secondary organic aerosol (SOA). Benzene is one of the most abundant species emitted from vehicles, biomass burning and industry. An iodide time-of-flight chemical ionisation mass spectrometer (ToF-CIMS) and nitrate ToF-CIMS were deployed at the Jülich Plant Atmosphere Chamber as part of a series of experiments examining benzene oxidation by OH under high- and low-NOx conditions, where a range of organic oxidation products were detected. The nitrate scheme detects many oxidation products with high masses, ranging from intermediate volatile organic compounds (IVOCs) to extremely low volatile organic compounds (ELVOCs), including C12 dimers. In comparison, very few species with C≥6 and O≥8 were detected with the iodide scheme, which detected many more IVOCs and semi-volatile organic compounds (SVOCs) but very few ELVOCs and low volatile organic compounds (LVOCs). A total of 132 and 195 CHO and CHON oxidation products are detected by the iodide ToF-CIMS in the low- and high-NOx experiments respectively. Ring-breaking products make up the dominant fraction of detected signal and 21 and 26 of the products listed in the Master Chemical Mechanism (MCM) were detected. The time series of highly oxidised (O≥6) and ring-retaining oxidation products (C6 and double-bond equivalent = 4) equilibrate quickly, characterised by a square form profile, compared to MCM and ring-breaking products which increase throughout oxidation, exhibiting sawtooth profiles. Under low-NOx conditions, all CHO formulae attributed to radical termination reactions of first-generation benzene products, and first-generation auto-oxidation products are observed. Several N-containing species that are either first-generation benzene products or first-generation auto-oxidation products are also observed under high-NOx conditions. Hierarchical cluster analysis finds four clusters, of which two describe photo-oxidation. Cluster 2 shows a negative dependency on the NO2/NOx ratio, indicating it is sensitive to NO concentration and thus likely to contain NO addition products and alkoxy-derived termination products. This cluster has the highest average carbon oxidation state (OSC‾) and the lowest average carbon number. Where nitrogen is present in a cluster member of cluster 2, the oxygen number is even, as expected for alkoxy-derived products. In contrast, cluster 1 shows no dependency on the NO2/NOx ratio and so is likely to contain more NO2 addition and peroxy-derived termination products. This cluster contains fewer fragmented species, as the average carbon number is higher and OSC‾ lower than cluster 2, and more species with an odd number of oxygen atoms. This suggests that clustering of time series which have features pertaining to distinct chemical regimes, for example, NO2/NOx perturbations, coupled with a priori knowledge, can provide insight into identification of potential functionality.

Published
2021
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14. Molecular composition and volatility of multi-generation products formed from isoprene oxidation by nitrate radical

Author

Wu, Rongrong, primary, Vereecken, Luc, additional, Tsiligiannis, Epameinondas, additional, Kang, Sungah, additional, Albrecht, Sascha R., additional, Hantschke, Luisa, additional, Zhao, Defeng, additional, Novelli, Anna, additional, Fuchs, Hendrik, additional, Tillmann, Ralf, additional, Hohaus, Thorsten, additional, Carlsson, Philip T. M., additional, Shenolikar, Justin, additional, Bernard, François, additional, Crowley, John N., additional, Fry, Juliane L., additional, Brownwood, Bellamy, additional, Thornton, Joel A., additional, Brown, Steven S., additional, Kiendler-Scharr, Astrid, additional, Wahner, Andreas, additional, Hallquist, Mattias, additional, and Mentel, Thomas F., additional

Published
2021
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15. Highly oxygenated organic molecule (HOM) formation in the isoprene oxidation by NO<sub>3</sub> radical

Author

Zhao, Defeng, primary, Pullinen, Iida, additional, Fuchs, Hendrik, additional, Schrade, Stephanie, additional, Wu, Rongrong, additional, Acir, Ismail-Hakki, additional, Tillmann, Ralf, additional, Rohrer, Franz, additional, Wildt, Jürgen, additional, Guo, Yindong, additional, Kiendler-Scharr, Astrid, additional, Wahner, Andreas, additional, Kang, Sungah, additional, Vereecken, Luc, additional, and Mentel, Thomas F., additional

Published
2021
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16. Chemical characterisation of benzene oxidation products under high and low NOx conditions using chemical ionisation mass spectrometry

Author

Priestley, Michael, Bannan, Thomas J., Breton, Michael, Worrall, Stephen D., Kang, Sungah, Pullinen, Iida, Schmitt, Sebastian, Tillmann, Ralf, Kleist, Einhard, Zhao, Defeng, Wildt, Jürgen, Garmash, Olga, Mehra, Archit, Bacak, Asan, Shallcross, Dudley E., Halquist, Åsa, Ehn, Mikael, Kiendler-Scharr, Astrid, Mentel, Thomas F., McFiggans, Gordon, Halquist, Mattias, Coe, Hugh, and Percival, Carl J.

Abstract

Aromatic hydrocarbons are a class of volatile organic compounds associated with anthropogenic activity and make up a significant fraction of urban VOC emissions that contribute to the formation of secondary organic aerosol (SOA). Benzene is one of the most abundant species emitted from vehicles, biomass burning and industry. An iodide time of flight chemical ionisation mass spectrometer (ToF-CIMS) and nitrate ToF-CIMS were deployed at the Jülich plant chamber as part of a series of experiments examining benzene oxidation by OH under high and low NOx conditions, where a range of organic oxidation products were detected. The nitrate scheme detects many oxidation products with high masses ranging from intermediate volatile organic compounds (IVOC) to extremely low volatile organic compounds (ELVOC), including C12 dimers. In comparison, very few species with C≥6 and O≥8 were detected with the iodide scheme, which detected many more IVOC and semi volatile organic compounds (SVOC) but very few ELVOC and low volatile organic compounds (LVOC). 132 and 195 CHO and CHON oxidation products are detected by the iodide ToF-CIMS in the low and high NOx experiments respectively. Ring breaking products make up the dominant fraction of detected signal (89–91 %). 21 and 26 of the products listed in the master chemical mechanism (MCM) were detected and account for 6.4–7.3 % of total signal. The time series of highly oxidised (O≥6) and ring retaining oxidation products (C6 and double bond equivalent = 4) equilibrate quickly characterised by a square form profile, compared to MCM and ring breaking products which increase throughout oxidation exhibiting saw tooth profiles. Under low NOx conditions, all CHO formulae attributed to radical termination reactions of 1st generation benzene products and 1st generation autoxidation products are observed, and one exclusively 2nd generation autoxidation product is also measured (C6H8O8). Several N containing species that are either 1st generation benzene products or 1st generation autoxidation products are also observed under high NOx conditions. Hierarchical cluster analysis finds four cluster of which two describe photo-oxidation. Cluster 2 shows a negative dependency on the NO2/NOx ratio indicating it is sensitive to NO concentration thus likely to contain NO addition products and alkoxy derived termination products. This cluster has the highest average carbon oxidation state (OSc) and the lowest average carbon number and where nitrogen is present in cluster member, the oxygen number is even, as expected for alkoxy derived products. In contrast, cluster 1 shows no dependency on the NO2/NOx ratio and so is likely to contain more NO2 addition and peroxy derived termination products. This cluster contains less fragmented species, as the average carbon number is higher and OSc lower than cluster 2, and more species with an odd number of oxygen atoms. This suggests clustering of time series which have features pertaining to distinct chemical regimes e.g. NO2/NOx perturbations, coupled with a priori knowledge, can provide insight into identification of potential functionality.

Published
2020

17. Chemical characterisation of benzene oxidation products under high- and low-NO<sub><i>x</i></sub> conditions using chemical ionisation mass spectrometry

Author

Priestley, Michael, primary, Bannan, Thomas J., additional, Le Breton, Michael, additional, Worrall, Stephen D., additional, Kang, Sungah, additional, Pullinen, Iida, additional, Schmitt, Sebastian, additional, Tillmann, Ralf, additional, Kleist, Einhard, additional, Zhao, Defeng, additional, Wildt, Jürgen, additional, Garmash, Olga, additional, Mehra, Archit, additional, Bacak, Asan, additional, Shallcross, Dudley E., additional, Kiendler-Scharr, Astrid, additional, Hallquist, Åsa M., additional, Ehn, Mikael, additional, Coe, Hugh, additional, Percival, Carl J., additional, Hallquist, Mattias, additional, Mentel, Thomas F., additional, and McFiggans, Gordon, additional

Published
2021
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18. Impact of NO<sub><i>x</i></sub> on secondary organic aerosol (SOA) formation from <i>α</i>-pinene and <i>β</i>-pinene photooxidation: the role of highly oxygenated organic nitrates

Author

Pullinen, Iida, primary, Schmitt, Sebastian, additional, Kang, Sungah, additional, Sarrafzadeh, Mehrnaz, additional, Schlag, Patrick, additional, Andres, Stefanie, additional, Kleist, Einhard, additional, Mentel, Thomas F., additional, Rohrer, Franz, additional, Springer, Monika, additional, Tillmann, Ralf, additional, Wildt, Jürgen, additional, Wu, Cheng, additional, Zhao, Defeng, additional, Wahner, Andreas, additional, and Kiendler-Scharr, Astrid, additional

Published
2020
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19. Impact of NOx on secondary organic aerosol (SOA) formation from α-pinene and β-pinene photooxidation: the role of highly oxygenated organic nitrates

Author

Pullinen, Iida, Schmitt, Sebastian, Tillmann, Ralf, Wildt, Jürgen, Wu, Cheng, Zhao, Defeng, Wahner, Andreas, Kiendler-Scharr, Astrid, Kang, Sungah, Sarrafzadeh, Mehrnaz, Schlag, Patrick, Andres, Stefanie, Kleist, Einhard, Mentel, Thomas F., Rohrer, Franz, and Springer, Monika

Subjects
ddc:550
Abstract

The formation of organic nitrates (ONs) in the gas phase and their impact on mass formation of secondary organic aerosol (SOA) was investigated in a laboratory study for α-pinene and β-pinene photooxidation. Focus was the elucidation of those mechanisms that cause the often observed suppression of SOA mass formation by NOx, and therein the role of highly oxygenated multifunctional molecules (HOMs). We observed that with increasing NOx concentration (a) the portion of HOM organic nitrates (HOM-ONs) increased, (b) the fraction of accretion products (HOM-ACCs) decreased, and (c) HOM-ACCs contained on average smaller carbon numbers.Specifically, we investigated HOM organic nitrates (HOM-ONs), arising from the termination reactions of HOM peroxy radicals with NOx, and HOM permutation products (HOM-PPs), such as ketones, alcohols, or hydroperoxides, formed by other termination reactions. Effective uptake coefficients γeff of HOMs on particles were determined. HOMs with more than six O atoms efficiently condensed on particles (γeff>0.5 on average), and for HOMs containing more than eight O atoms, every collision led to loss. There was no systematic difference in γeff for HOM-ONs and HOM-PPs arising from the same HOM peroxy radicals. This similarity is attributed to the multifunctional character of the HOMs: as functional groups in HOMs arising from the same precursor HOM peroxy radical are identical, vapor pressures should not strongly depend on the character of the final termination group. As a consequence, the suppressing effect of NOx on SOA formation cannot be simply explained by replacement of terminal functional groups by organic nitrate groups.According to their γeff all HOM-ONs with more than six O atoms will contribute to organic bound nitrate (OrgNO3) in the particulate phase. However, the fraction of OrgNO3 stored in condensable HOMs with molecular masses > 230 Da appeared to be substantially higher than the fraction of particulate OrgNO3 observed by aerosol mass spectrometry. This result suggests losses of OrgNO3 for organic nitrates in particles, probably due to hydrolysis of OrgNO3 that releases HNO3 into the gas phase but leaves behind the organic rest in the particulate phase. However, the loss of HNO3 alone could not explain the observed suppressing effect of NOx on particle mass formation from α-pinene and β-pinene.Instead we can attribute most of the reduction in SOA mass yields with increasing NOx to the significant suppression of gas phase HOM-ACCs, which have high molecular mass and are potentially important for SOA mass formation at low-NOx conditions.

Published
2020
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21. Molecular composition and volatility of multi-generation products formed from isoprene oxidation by nitrate radical.

Author

Wu, Rongrong, Vereecken, Luc, Tsiligiannis, Epameinondas, Kang, Sungah, Albrecht, Sascha R., Hantschke, Luisa, Zhao, Defeng, Novelli, Anna, Fuchs, Hendrik, Tillmann, Ralf, Hohaus, Thorsten, Carlsson, Philip T. M., Shenolikar, Justin, Bernard, François, Crowley, John N., Fry, Juliane L., Brownwood, Bellamy, Thornton, Joel A., Brown, Steven S., and Kiendler-Scharr, Astrid

Abstract

Isoprene oxidation by nitrate radical (NO3) is a potentially important source of secondary organic aerosol (SOA). It is suggested that the second or later-generation products are the more substantial contributors to SOA. However, there are few studies investigating the multi-generation chemistry of isoprene-NO3 reaction, and information about the volatility of different isoprene nitrates, which is essential to evaluate their potential to form SOA and determine their atmospheric fate, is rare. In this work, we studied the reaction between isoprene and NO3 in the SAPHIR chamber (Jülich) under near atmospheric conditions. Various oxidation products were measured by a high-resolution time-of-flight chemical ionization mass spectrometer using Br as the reagent ion. They are grouped into monomers (C4- and C5-products), and dimers (C10-products) with 1–3 nitrate groups according to their chemical composition. Most of the observed products match expected termination products observed in previous studies, but some compounds such as monomers and dimers with three nitrogen atoms were rarely reported in the literature as gas-phase products from isoprene oxidation by NO3. Possible formation mechanisms for these compounds are proposed. The multi-generation chemistry of isoprene and NO3 is characterized by taking advantages of the time behavior of different products. In addition, the vapor pressures of diverse isoprene nitrates are calculated by different parametrization methods. An estimation of the vapor pressure is also derived from their condensation behavior. According to our results, isoprene monomers belong to intermediate volatility or semi-volatile organic compounds and thus have little effect on SOA formation. In contrast, the dimers are expected to have low or extremely low volatility, indicating that they are potentially substantial contributors to SOA. However, the monomers constitute 80 % of the total explained signals on average, while the dimers contribute less than 2 %, suggesting that the contribution of isoprene NO3 oxidation to SOA by condensation should be low under atmospheric conditions. We expect a SOA mass yield of about 5 % from the wall loss and dilution corrected mass concentrations, assuming that all of the isoprene dimers in the low- or extremely low-volatility organic compound (LVOC or ELVOC) range will condense completely. [ABSTRACT FROM AUTHOR]

Published
2020
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22. Chemical characterisation of benzene oxidation products under high and low NOx conditions using chemical ionisation mass spectrometry.

Author

Priestley, Michael, Bannan, Thomas J., Breton, Michael Le, Worrall, Stephen D., Kang, Sungah, Pullinen, Iida, Schmitt, Sebastian, Tillmann, Ralf, Kleist, Einhard, Zhao, Defeng, Wildt, Jürgen, Garmash, Olga, Mehra, Archit, Bacak, Asan, Shallcross, Dudley E., Halquist, Åsa, Ehn, Mikael, Kiendler-Scharr, Astrid, Mentel, Thomas F., and McFiggans, Gordon

Abstract

Aromatic hydrocarbons are a class of volatile organic compounds associated with anthropogenic activity and make up a significant fraction of urban VOC emissions that contribute to the formation of secondary organic aerosol (SOA). Benzene is one of the most abundant species emitted from vehicles, biomass burning and industry. An iodide time of flight chemical ionisation mass spectrometer (ToF-CIMS) and nitrate ToF-CIMS were deployed at the Jülich plant chamber as part of a series of experiments examining benzene oxidation by OH under high and low NOx conditions, where a range of organic oxidation products were detected. The nitrate scheme detects many oxidation products with high masses ranging from intermediate volatile organic compounds (IVOC) to extremely low volatile organic compounds (ELVOC), including C12 dimers. In comparison, very few species with C≥6 and O≥8 were detected with the iodide scheme, which detected many more IVOC and semi volatile organic compounds (SVOC) but very few ELVOC and low volatile organic compounds (LVOC). 132 and 195 CHO and CHON oxidation products are detected by the iodide ToF-CIMS in the low and high NOx experiments respectively. Ring breaking products make up the dominant fraction of detected signal (89-91 %). 21 and 26 of the products listed in the master chemical mechanism (MCM) were detected and account for 6.4-7.3 % of total signal. The time series of highly oxidised (O≥6) and ring retaining oxidation products (C6 and double bond equivalent = 4) equilibrate quickly characterised by a square form profile, compared to MCM and ring breaking products which increase throughout oxidation exhibiting saw tooth profiles. Under low NOx conditions, all CHO formulae attributed to radical termination reactions of 1st generation benzene products and 1st generation autoxidation products are observed, and one exclusively 2nd generation autoxidation product is also measured (C6H8O8). Several N containing species that are either 1st generation benzene products or 1st generation autoxidation products are also observed under high NOx conditions. Hierarchical cluster analysis finds four cluster of which two describe photo-oxidation. Cluster 2 shows a negative dependency on the NO2/NOx ratio indicating it is sensitive to NO concentration thus likely to contain NO addition products and alkoxy derived termination products. This cluster has the highest average carbon oxidation state (OSc) and the lowest average carbon number and where nitrogen is present in cluster member, the oxygen number is even, as expected for alkoxy derived products. In contrast, cluster 1 shows no dependency on the NO2/NOx ratio and so is likely to contain more NO2 addition and peroxy derived termination products. This cluster contains less fragmented species, as the average carbon number is higher and OSc lower than cluster 2, and more species with an odd number of oxygen atoms. This suggests clustering of time series which have features pertaining to distinct chemical regimes e.g. NO2/NOx perturbations, coupled with a priori knowledge, can provide insight into identification of potential functionality. [ABSTRACT FROM AUTHOR]

Published
2020
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24. Measurements of highly oxidized multifunctional compounds from isoprene NO3 reaction using bromide chemical ionization mass spectrometry.

Author

Wu, Rongrong, Kang, Sungah, Albrecht, Sascha, Hantschke, Luisa, Tsiligiannis, Epameinondas, Hallquist, Mattias, and Mentel, Thomas F.

Subjects
*CHEMICAL ionization mass spectrometry, *MASS spectrometers, *MEASURING instruments, *SALICYLIC acid, *BROMIDES
Abstract

Highly oxidized multifunctional molecules (HOMs) play a significant role in aerosolformation. They are expected to be reactive and with low volatility, which makes theirmeasurement challenging. In this study, a high-resolution time-of-flight chemical ionizationmass spectrometer (HR-ToF-CIMS) using bromide as primary reagent ion was deployed tomeasure HOMs. Calibration experiments were performed using salicylic acid (C7H6O3) asa calibration compound. The limit of detection is 0.8 ppt for a 1 min integrationmeasurement, and the measurement sensitivity is approximately 112 ± 20 cps ppt−1.Experiments were performed using this instrument in the atmospheric simulationchamber SAPHIR (Simulation of Atmospheric PHotochemistry In a large ReactionChamber) in Forschungszentrum Jülich to measure HOMs formed from oxidation ofisoprene through reaction with nitrate radicals in August 2018. Perfluoropentanoic acid(C5HF9O2) was used as an internal standard to check the stability of the instrument. Inaddition, the instrument performance was tested by comparison with more widely-usediodide chemical-ionization mass spectrometer. Both measurements show that C5nitrooxy hydroperoxide and dihydroxy nitrate (C5H9NO5), C5 hydroxy nitrate(C5H9NO4), C5 hydroxy hydroperoxy nitrate (C5H9NO6), C5 hydroxy carbonylnitrate (C5H7NO5) were the major oxidation products, and a linear correlationcoefficient 0.85 was achieved between two datasets. The slopes of linear regression formost species varied from 0.76 to 2.0, which indicated a relatively good agreementof two instruments. All these facts demonstrate that bromide CIMS used in thisstudy is a reliable instrument to measure HOMs. A preliminary comparison of thechemical box model simulated and observed HOMs concentrations will be presented. [ABSTRACT FROM AUTHOR]

Published
2019

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