Your search keyword '"Hohaus, Thorsten"' showing total 23 results

1. Development of a multiphase chemical mechanism to improve secondary organic aerosol formation in CAABA/MECCA (version 4.7.0).

Author

Wieser, Felix, Sander, Rolf, Cho, Changmin, Fuchs, Hendrik, Hohaus, Thorsten, Novelli, Anna, Tillmann, Ralf, and Taraborrelli, Domenico

Subjects

ORGANIC chemistry, HENRY'S law, CHEMICAL models, AEROSOLS, VOLATILE organic compounds, CARBONACEOUS aerosols, OXIDATION

Abstract

During the last few decades, the impact of multiphase chemistry on secondary organic aerosols (SOAs) has been demonstrated to be the key to explaining laboratory experiments and field measurements. However, global atmospheric models still show large biases when simulating atmospheric observations of organic aerosols (OAs). Major reasons for the model errors are the use of simplified chemistry schemes of the gas-phase oxidation of vapours and the parameterization of heterogeneous surface reactions. The photochemical oxidation of anthropogenic and biogenic volatile organic compounds (VOCs) leads to products that either produce new SOA or are taken up by existing aqueous media like cloud droplets and deliquescent aerosols. After partitioning, aqueous-phase processing results in polyols, organosulfates, and other products with a high molar mass and oxygen content. In this work, we introduce the formation of new low-volatility organic compounds (LVOCs) to the multiphase chemistry box model CAABA/MECCA. Most notable are the additions of the SOA precursors, limonene and n -alkanes (5 to 8 C atoms), and a semi-explicit chemical mechanism for the formation of LVOCs from isoprene oxidation in the gas and aqueous phases. Moreover, Henry's law solubility constants and their temperature dependences are estimated for the partitioning of organic molecules to the aqueous phase. Box model simulations indicate that the new chemical scheme predicts the enhanced formation of LVOCs, which are known for being precursor species to SOAs. As expected, the model predicts that LVOCs are positively correlated to temperature but negatively correlated to NOx levels. However, the aqueous-phase processing of isoprene epoxydiols (IEPOX) displays a more complex dependence on these two key variables. Semi-quantitative comparison with observations from the SOAS campaign suggests that the model may overestimate methylbutane-1,2,3,4-tetrol (MeBuTETROL) from IEPOX. Further application of the mechanism in the modelling of two chamber experiments, one in which limonene is consumed by ozone and one in which isoprene is consumed by NO3 shows a sufficient agreement with experimental results within model limitations. The extensions in CAABA/MECCA are transferred to the 3D atmospheric model MESSy for a comprehensive evaluation of the impact of aqueous- and/or aerosol-phase chemistry on SOA at a global scale in a follow-up study. [ABSTRACT FROM AUTHOR]

Published

2024

2. 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

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

Subjects

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

Abstract

Highly oxygenated molecules (HOM) from the atmospheric oxidation of biogenic volatile organic compounds are important contributors to secondary organic aerosol (SOA). Organic peroxy radicals (RO2) and hydroperoxy radicals (HO2) are key species influencing the HOM product distribution. In laboratory studies experimental requirements often result in overemphasis of RO2 cross-reactions compared to reactions of RO2 with HO2. 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 their fraction remaining in the gas phase after seeding with (NH4)2SO4 aerosol. Increase of 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. Particle phase observations measured an about according decrease in SOA mass and yield. Our study showed that too low HO2/RO2 ratios compared to the atmosphere can lead to an overestimation of SOA yields. [ABSTRACT FROM AUTHOR]

Published

2023

4. Seasonal variation in nitryl chloride and its relation to gas-phase precursors during the JULIAC campaign in Germany

Author

Tan, Zhaofeng, Fuchs, Hendrik, Hofzumahaus, Andreas, Bloss, William J., Bohn, Birger, Cho, Changmin, Hohaus, Thorsten, Holland, Frank, Lakshmisha, Chandrakiran, Liu, Lu, Monks, Paul S., Novelli, Anna, Niether, Doreen, Rohrer, Franz, Tillmann, Ralf, Valkenburg, Thalassa S. E., Vardhan, Vaishali, Kiendler-Scharr, Astrid, Wahner, Andreas, Sommariva, Roberto, Tan, Zhaofeng, Fuchs, Hendrik, Hofzumahaus, Andreas, Bloss, William J., Bohn, Birger, Cho, Changmin, Hohaus, Thorsten, Holland, Frank, Lakshmisha, Chandrakiran, Liu, Lu, Monks, Paul S., Novelli, Anna, Niether, Doreen, Rohrer, Franz, Tillmann, Ralf, Valkenburg, Thalassa S. E., Vardhan, Vaishali, Kiendler-Scharr, Astrid, Wahner, Andreas, and Sommariva, Roberto

Abstract

Ambient measurements of nitryl chloride (ClNO2) were performed at a rural site in Germany, covering three periods in winter, summer, and autumn 2019, as part of the JULIAC campaign (Julich Atmospheric Chemistry Project) that aimed to understand the photochemical processes in air masses typical of midwestern Europe. Measurements were conducted at 50 m aboveground, which was mainly located in the nocturnal boundary layer and thus uncoupled from local surface emissions. ClNO2 is produced at night by the heterogeneous reaction of dinitrogen pentoxide (N2O5) on chloride (Cl-) that contains aerosol. Its photolysis during the day is of general interest, as it produces chlorine (Cl) atoms that react with different atmospheric trace gases to form radicals. The highest-observed ClNO2 mixing ratio was 1.6 ppbv (parts per billion by volume; 15 min average) during the night of 20 September. Air masses reaching the measurement site either originated from long-range transport from the southwest and had an oceanic influence or circulated in the nearby region and were influenced by anthropogenic activities. Nocturnal maximum ClNO(2 )mixing ratios were around 0.2 ppbv if originating from long-range transport in nearly all seasons, while the values were higher, ranging from 0.4 to 0.6 ppbv for regionally influenced air. The chemical composition of long-range transported air was similar in all investigated seasons, while the regional air exhibited larger differences between the seasons. The N2O5 necessary for ClNO2 formation comes from the reaction of nitrate radicals (NO3) with nitrogen dioxide (NO2), where NO3 itself is formed by a reaction of NO2 with ozone (O-3). Measured concentrations of ClNO2, NO2, and O(3 )were used to quantify ClNO(2 )production efficiencies, i.e., the yield of ClNO2 formation per NO3 radical formed, and a box model was used to examine the idealized dependence of ClNO2 on the observed nocturnal O(3 )and NO2 concentrations. Results indicate that ClNO(2 )product

Published

2022

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, and Reimer, David

Subjects

HYDROPEROXIDES, METHYL vinyl ketone, WEATHER, UNIMOLECULAR reactions, ATMOSPHERIC ozone, ISOPRENE, ISOMERS, OXIDATION

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. [ABSTRACT FROM AUTHOR]

Published

2023

6. Experimental chemical budgets of OH, HO2, and RO2 radicals in rural air in western Germany during the JULIAC campaign 2019.

Author

Cho, Changmin, Fuchs, Hendrik, Hofzumahaus, Andreas, Holland, Frank, Bloss, William J., Bohn, Birger, Dorn, Hans-Peter, Glowania, Marvin, Hohaus, Thorsten, Liu, Lu, Monks, Paul S., Niether, Doreen, Rohrer, Franz, Sommariva, Roberto, Tan, Zhaofeng, Tillmann, Ralf, Kiendler-Scharr, Astrid, Wahner, Andreas, and Novelli, Anna

Subjects

TRACE gases, PEROXY radicals, LASER-induced fluorescence, RADICALS (Chemistry), DECIDUOUS forests, SPRING, SUMMER

Abstract

Photochemical processes in ambient air were studied using the atmospheric simulation chamber SAPHIR at Forschungszentrum Jülich, Germany. Ambient air was continuously drawn into the chamber through a 50 m high inlet line and passed through the chamber for 1 month in each season throughout 2019. The residence time of the air inside the chamber was about 1 h. As the research center is surrounded by a mixed deciduous forest and is located close to the city Jülich, the sampled air was influenced by both anthropogenic and biogenic emissions. Measurements of hydroxyl (OH), hydroperoxyl (HO 2), and organic peroxy (RO 2) radicals were achieved by a laser-induced fluorescence instrument. The radical measurements together with measurements of OH reactivity (kOH , the inverse of the OH lifetime) and a comprehensive set of trace gas concentrations and aerosol properties allowed for the investigation of the seasonal and diurnal variation of radical production and destruction pathways. In spring and summer periods, median OH concentrations reached 6 × 10 6 cm -3 at noon, and median concentrations of both HO 2 and RO 2 radicals were 3 × 10 8 cm -3. The measured OH reactivity was between 4 and 18 s -1 in both seasons. The total reaction rate of peroxy radicals with NO was found to be consistent with production rates of odd oxygen (O x= NO 2+ O 3) determined from NO 2 and O 3 concentration measurements. The chemical budgets of radicals were analyzed for the spring and summer seasons, when peroxy radical concentrations were above the detection limit. For most conditions, the concentrations of radicals were mainly sustained by the regeneration of OH via reactions of HO 2 and RO 2 radicals with nitric oxide (NO). The median diurnal profiles of the total radical production and destruction rates showed maxima between 3 and 6 ppbv h -1 for OH, HO 2 , and RO 2. Total RO X (OH, HO 2 , and RO 2) initiation and termination rates were below 3 ppbv h -1. The highest OH radical turnover rate of 13 ppbv h -1 was observed during a high-temperature (max. 40 ∘ C) period in August. In this period, the highest HO 2 , RO 2 , and RO X turnover rates were around 11, 10, and 4 ppbv h -1 , respectively. When NO mixing ratios were between 1 and 3 ppbv, OH and HO 2 production and destruction rates were balanced, but unexplained RO 2 and RO X production reactions with median rates of 2 and 0.4 ppbv h -1 , respectively, were required to balance their destruction. For NO mixing ratios above 3 ppbv, the peroxy radical reaction rates with NO were highly uncertain due to the low peroxy radical concentrations close to the limit of NO interferences in the HO 2 and RO 2 measurements. For NO mixing ratios below 1 ppbv, a missing source for OH and a missing sink for HO 2 were found with maximum rates of 3.0 and 2.0 ppbv h -1 , respectively. The missing OH source likely consisted of a combination of a missing inter-radical HO 2 to OH conversion reaction (up to 2 ppbv h -1) and a missing primary radical source (0.5–1.4 ppbv h -1). The dataset collected in this campaign allowed analyzing the potential impact of OH regeneration from RO 2 isomerization reactions from isoprene, HO 2 uptake on aerosol, and RO 2 production from chlorine chemistry on radical production and destruction rates. These processes were negligible for the chemical conditions encountered in this study. [ABSTRACT FROM AUTHOR]

Published

2023

7. Experimental chemical budgets of OH, HO2 and RO2 radicals in rural air in West-Germany during the JULIAC campaign 2019.

Author

Cho, Changmin, Fuchs, Hendrik, Hofzumahaus, Andreas, Holland, Frank, Bloss, William J., Bohn, Birger, Dorn, Hans-Peter, Glowania, Marvin, Hohaus, Thorsten, Liu, Lu, Monks, Paul S., Niether, Doreen, Rohrer, Franz, Sommariva, Roberto, Tan, Zhaofeng, Tillmann, Ralf, Kiendler-Scharr, Astrid, Wahner, Andreas, and Novelli, Anna

Subjects

BUDGET, CHLORINE, NITRIC oxide, SUMMER, HIGH temperatures

Abstract

Photochemical processes in ambient air were studied using the atmospheric simulation chamber SAPHIR at Forschungszentrum Jülich, Germany. Ambient air was continuously drawn into the chamber through a 50 m high inlet line and passed through the chamber for one month in each season throughout 2019. The residence time of the air inside the chamber was about one hour. As the research centre is surrounded by a mixed deciduous forest and is located close to the city Jülich, the sampled air was influenced by both anthropogenic and biogenic emissions. Measurements of hydroxyl (OH), hydroperoxyl (HO2) and organic peroxy (RO2) radicals were achieved by a laser-induced fluorescence instrument. The radical measurements together with measurements of OH reactivity (k OH, the inverse of the OH lifetime) and a comprehensive set of trace gas concentrations and aerosol properties allowed for the investigation of the seasonal and diurnal variation of radical production and destruction pathways. In spring and summer periods, median OH concentrations reached 6 × 106 cm-3 at noon, and median concentrations of both, HO2 and RO2 radicals, were 3 × 108 cm-3. The measured OH reactivity was between 4 and 18 s-1 in both seasons. The total reaction rate of peroxy radicals with NO was found to be consistent with production rates of odd oxygen (OX = NO2+O3) determined from NO2 and O3 concentration measurements. The chemical budgets of radicals were analysed for the spring and summer seasons, when peroxy radical concentrations were above the detection limit. For most conditions, the concentrations of radicals were mainly sustained by the regeneration of OH via reactions of HO2 and RO2 radicals with nitric oxide (NO). The median diurnal profiles of the total radical production and destruction rates showed maxima between 3 to 8 ppbv h-1 for OH, HO2 and RO2. Total ROX (OH, HO2, and RO2) initiation and termination rates were below 3 ppbv h-1. The highest OH radical turnover rate of 13 ppbv h-1 was observed during a high-temperature (max 40°C) period in August. In this period, the highest HO2, RO2 and ROX turnover rates were around 11, 10 and 4 ppbv h-1, respectively. When NO mixing ratios were between 1 ppbv to 3 ppbv, OH and HO2 production and destruction rates were balanced, but unexplained RO2 and ROX production reactions with median rates of 2 ppbv h-1 and 0.4 ppbv h-1, respectively, were required to balance their destruction. For NO mixing ratios above 3 ppbv, the peroxy radical reaction rates with NO were highly uncertain due to the low peroxy radical concentrations close to the limit of NO interferences in the HO2 and RO2 measurements. For NO mixing ratios below 1 ppbv, a missing OH source with a rate of up to 3.0 ppbv h-1 was found. This missing OH source consists likely of a combination of a missing primary radical source (0.5 ~ 1.4 ppbv h-1) and a missing inter-radical HO2 to OH conversion reaction with a rate of up to 2.5 ppbv h-1. The dataset collected in this campaign allowed to analyze the potential impact of OH regeneration from RO2 isomerization reactions from isoprene, HO2 uptake on aerosol, and RO2 production from chlorine chemistry on radical production and destruction rates. These processes were negligible for the chemical conditions encountered in this study. [ABSTRACT FROM AUTHOR]

Published

2022

8. Comparison of isoprene chemical mechanisms at 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, and Reimer, David

Subjects

ISOPRENE, OXIDATION, ALDEHYDES, EPOXY resins, NITRATES

Abstract

The gas-phase reaction of isoprene with the nitrate radical (NO3) was investigated in experiments in the outdoor SAPHIR chamber at 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 conformer. (2) The chemical mechanism derived from experiments in the CalTech chamber, which considers different RO2 conformers. (3) The FZJ-NO3 isoprene mechanism derived from quantum chemical calculations, which in addition to the CalTech mechanism includes equilibrium reactions of RO2 conformers, 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 aldehydes (HPALD), which are specific for 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, epoxy compounds, which are specific for 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 an accurate simulation of the measured 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 products species such as nitrate hydroperoxides, nitrate carbonyl, 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 not relevant on the typical time scale of one night (12 hours). 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. [ABSTRACT FROM AUTHOR]

Published

2022

9. Seasonal variation of nitryl chloride and its relation to gas-phase precursors during the JULIAC campaign in Germany.

Author

Zhaofeng Tan, Fuchs, Hendrik, Hofzumahaus, Andreas, Bloss, William J., Bohn, Birger, Changmin Cho, Hohaus, Thorsten, Holland, Frank, Lakshmisha, Chandrakiran, Lu Liu, Monks, Paul S., Novelli, Anna, Niether, Doreen, Rohrer, Franz, Tillmann, Ralf, Valkenburg, Thalassa, Vardhan, Vaishali, Kiendler-Scharr, Astrid, Wahner, Andreas, and Sommariva, Roberto

Abstract

Ambient measurements of nitryl chloride (ClNO2) were performed at a rural site in Germany covering 3 periods in winter, summer, and autumn 2019 as part of the JULIAC campaign (Jülich Atmospheric Chemistry Project) that aimed for understanding the photochemical processes in air masses typical for mid-west Europe. Measurements were conducted at 50 m above ground, which was most located mainly at the nocturnal boundary layer and thus uncoupled from local surface emissions. ClNO2 is produced at nighttime by heterogeneous reaction of dinitrogen pentoxide (N2O5) on chloride ion (Cl-) containing aerosol. Its photolysis at day is of general interest as it produces chlorine (Cl) atoms that react with different atmospheric trace gases forming radicals. The highest observed ClNO2 mixing ratio was 1.6 ppbv (15-min average) in the middle of one night in September. Air masses reaching the measurement site either originated from long-range transport from the southwest and had an oceanic influence or circulated in the nearby region and were influenced by anthropogenic activities. Nocturnal maximum ClNO2 mixing ratios were around 0.2 ppbv if originating from long-range transport in nearly all seasons, while values were higher ranging from 0.4 to 0.6 ppbv for regionally influenced air. The chemical composition of long-range transported air was similar in all investigated seasons, while the regional air exhibited larger differences between the seasons. The N2O5 necessary for ClNO2 formation comes from the reaction of nitrate radicals (NO3) with nitrogen dioxide 29 (NO2), where NO3 itself is formed by reaction of NO2 with ozone (O3). Measured concentrations of ClNO2, NO2 and O3 were used to quantify ClNO2 production efficiencies, i.e., the yield of ClNO2 formation per NO3 radical formed, and a box model was used to examine the idealized dependence of ClNO2 on the observed nocturnal O3 and NO2 concentrations. Results indicate that ClNO2 production efficiency was most sensitive to the availability of NO2 rather than that of O3 and increase with decreasing temperature. The average ClNO2 production efficiency was highest in February and September with values of 18% and was lowest in December with values of 3%. The average ClNO2 production efficiencies were in the range of 3 and 6 % from August to November for air masses originating from long-range transportation. These numbers are at the high end of values reported in literature indicating the importance of ClNO2 chemistry in rural environments in mid39 west Europe. [ABSTRACT FROM AUTHOR]

Published

2022

10. Are reactive oxygen species (ROS) a suitable metric to predict toxicity of carbonaceous aerosol particles?

Author

Zhang, Zhi-Hui, Hartner, Elena, Utinger, Battist, Gfeller, Benjamin, Paul, Andreas, Sklorz, Martin, Czech, Hendryk, Yang, Bin Xia, Su, Xin Yi, Jakobi, Gert, Orasche, Jürgen, Schnelle-Kreis, Jürgen, Jeong, Seongho, Gröger, Thomas, Pardo, Michal, Hohaus, Thorsten, Adam, Thomas, Kiendler-Scharr, Astrid, Rudich, Yinon, and Zimmermann, Ralf

Subjects

CARBONACEOUS aerosols, REACTIVE oxygen species, EPITHELIAL cell culture, VOLATILE organic compounds, AEROSOLS, EXPOSURE dose

Abstract

It is being suggested that particle-bound or particle-induced reactive oxygen species (ROS), which significantly contribute to the oxidative potential (OP) of aerosol particles, are a promising metric linking aerosol compositions to toxicity and adverse health effects. However, accurate ROS quantification remains challenging due to the reactive and short-lived nature of many ROS components and the lack of appropriate analytical methods for a reliable quantification. Consequently, it remains difficult to gauge their impact on human health, especially to identify how aerosol particle sources and atmospheric processes drive particle-bound ROS formation in a real-world urban environment. In this study, using a novel online particle-bound ROS instrument (OPROSI), we comprehensively characterized and compared the formation of ROS in secondary organic aerosols (SOAs) generated from organic compounds that represent anthropogenic (naphthalene, SOA NAP) and biogenic (β -pinene, SOA βPIN) precursors. The SOA mass was condensed onto soot particles (SP) under varied atmospherically relevant conditions (photochemical aging and humidity) to mimic the SOA formation from a mixing of traffic-related carbonaceous primary aerosols and volatile organic compounds (VOCs). We systematically analyzed the ability of the aqueous extracts of the two aerosol types (SOA NAP -SP and SOA βPIN -SP) to induce ROS production and OP. We further investigated cytotoxicity and cellular ROS production after exposing human lung epithelial cell cultures (A549) to extracts of the two aerosols. A significant finding of this study is that more than 90 % of all ROS components in both SOA types have a short lifetime, highlighting the need to develop online instruments for a meaningful quantification of ROS. Our results also show that photochemical aging promotes particle-bound ROS production and enhances the OP of the aerosols. Compared to SOA βPIN -SP, SOA NAP -SP elicited a higher acellular and cellular ROS production, a higher OP, and a lower cell viability. These consistent results between chemical-based and biological-based analyses indicate that particle-bound ROS quantification could be a feasible metric to predict aerosol particle toxicity and adverse human effects. Moreover, the cellular ROS production caused by SOA exposure not only depends on aerosol type but is also affected by exposure dose, highlighting a need to mimic the process of particle deposition onto lung cells and their interactions as realistically as possible to avoid unknown biases. [ABSTRACT FROM AUTHOR]

Published

2022

11. Are reactive oxygen species (ROS) a suitable metric to predict toxicity of carbonaceous aerosol particles?

Author

Zhi-Hui Zhang, Hartner, Elena, Utinger, Battist, Gfeller, Benjamin, Paul, Andreas, Sklorz, Martin, Czech, Hendryk, Bin Xia Yang, Xin Yi Su, Jakobi, Gert, Orasche, Jürgen, Schnelle-Kreis, Jürgen, Seongho Jeong, Gröger, Thomas, Pardo, Michal, Hohaus, Thorsten, Adam, Thomas, Kiendler-Scharr, Astrid, Rudich, Yinon, and Zimmermann, Ralf

Abstract

It is being suggested that particle-bound or particle-induced reactive oxygen species (ROS), which significantly contribute to the oxidative potential (OP) of aerosol particles, are a promising metric linking aerosol compositions to toxicity and adverse health effects. However, accurate ROS quantification remains challenging due to the reactive and short-lived nature of many ROS components and the lack of appropriate analytical methods for a reliable quantification. Consequently, it remains difficult to gauge their impact on human health, especially to identify how aerosol particle sources and atmospheric processes drive particle-bound ROS formation in a real-world urban environment. In this study, using a novel online particle-bound ROS instrument (OPROSI), we comprehensively characterized and compared the formation of ROS in secondary organic aerosols (SOA) generated from organic compounds that represent anthropogenic (naphthalene, SOANAP) and biogenic (β-pinene, SOAβPIN) precursors. The SOA mass was condensed onto soot particles (SP) under varied atmospherically relevant conditions (photochemical aging and humidity). We systematically analysed the ability of the aqueous extracts of the two aerosol types (SOANAP-SP and SOAβPIN-SP) to induce ROS production and OP. We further investigated cytotoxicity and cellular ROS production after exposing human lung epithelial cell cultures (A549) to extracts of the two aerosols. A significant finding of this study is that more than 90% of all ROS components in both SOA types have a short lifetime, highlighting the need to develop online instruments for a meaningful quantification of ROS. Our results also show that photochemical aging promotes particle-bound ROS production and enhances the OP of the aerosols. Compared to SOAβPIN-SP, SOANAP-SP elicited a higher acellular and cellular ROS production, a higher OP and a lower cell viability. These consistent results between chemical-based and biological-based analyses indicate that particle-bound ROS quantification could be a feasible metric to predict aerosol particle toxicity and adverse human effects. Moreover, the cellular ROS production caused by SOA exposure not only depends on aerosol type, but is also affected by exposure dose, highlighting a need to mimic the process of particle deposition onto lung cells and their interactions as realistically as possible to avoid unknown biases. [ABSTRACT FROM AUTHOR]

Published

2021

12. 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

Subjects

CHEMICAL ionization mass spectrometry, SEMIVOLATILE organic compounds, ISOPRENE, DIMERS, VAPOR pressure, NITRATES, ORGANIC compounds

Abstract

Isoprene oxidation by nitrate radical (NO 3) 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-NO 3 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 NO 3 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. Most of the products detected are organic nitrates, and they are grouped into monomers (C 4 and C 5 products) and dimers (C 10 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 NO 3. Possible formation mechanisms for these compounds are proposed. The multi-generation chemistry of isoprene and NO 3 is characterized by taking advantage 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 NO 3 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

2021

13. 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

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

Author

Rongrong Wu, Vereecken, Luc, Tsiligiannis, Epameinondas, Sungah Kang, Albrecht, Sascha R., Hantschke, Luisa, Defeng Zhao, 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

15. Mutual promotion between aerosol particle liquid water and particulate nitrate enhancement leads to severe nitrate-dominated particulate matter pollution and low visibility.

Author

Wang, Yu, Chen, Ying, Wu, Zhijun, Shang, Dongjie, Bian, Yuxuan, Du, Zhuofei, Schmitt, Sebastian H., Su, Rong, Gkatzelis, Georgios I., Schlag, Patrick, Hohaus, Thorsten, Voliotis, Aristeidis, Lu, Keding, Zeng, Limin, Zhao, Chunsheng, Alfarra, M. Rami, McFiggans, Gordon, Wiedensohler, Alfred, Kiendler-Scharr, Astrid, and Zhang, Yuanhang

Subjects

PARTICULATE nitrate, PARTICULATE matter, AEROSOLS, POLLUTION, AIR quality, INDUSTRIAL pollution, NITROGEN oxides, CARBONACEOUS aerosols

Abstract

As has been the case in North America and western Europe, the SO2 emissions have substantially reduced in the North China Plain (NCP) in recent years. Differential rates of reduction in SO2 and NOx concentrations result in the frequent occurrence of particulate matter pollution dominated by nitrate (pNO3-) over the NCP. In this study, we observed a polluted episode with the particulate nitrate mass fraction in nonrefractory PM 1 (NR-PM 1) being up to 44 % during wintertime in Beijing. Based on this typical pNO3- -dominated haze event, the linkage between aerosol water uptake and pNO3- enhancement, further impacting on visibility degradation, has been investigated based on field observations and theoretical calculations. During haze development, as ambient relative humidity (RH) increased from ∼10 % to 70 %, the aerosol particle liquid water increased from ∼1 µgm-3 at the beginning to ∼75 µgm-3 in the fully developed haze period. The aerosol liquid water further increased the aerosol surface area and volume, enhancing the condensational loss of N2O5 over particles. From the beginning to the fully developed haze, the condensational loss of N2O5 increased by a factor of 20 when only considering aerosol surface area and volume of dry particles, while increasing by a factor of 25 when considering extra surface area and volume due to water uptake. Furthermore, aerosol liquid water favored the thermodynamic equilibrium of HNO3 in the particle phase under the supersaturated HNO3 and NH3 in the atmosphere. All the above results demonstrated that pNO3- is enhanced by aerosol water uptake with elevated ambient RH during haze development, in turn facilitating the aerosol take-up of water due to the hygroscopicity of particulate nitrate salt. Such mutual promotion between aerosol particle liquid water and particulate nitrate enhancement can rapidly degrade air quality and halve visibility within 1 d. Reduction of nitrogen-containing gaseous precursors, e.g., by control of traffic emissions, is essential in mitigating severe haze events in the NCP. [ABSTRACT FROM AUTHOR]

Published

2020

16. Mutual promotion effect between aerosol particle liquid water and nitrate formation lead to severe nitrate-dominated particulate matter pollution and low visibility.

Author

Yu Wang, Ying Chen, Zhijun Wu, Dongjie Shang, Yuxuan Bian, Zhuofei Du, Schmitt, Sebastian H., Rong Su, Gkatzelis, Georgios I., Schlag, Patrick, Hohaus, Thorsten, Voliotis, Aristeidis, Keding Lu, Limin Zeng, Chunsheng Zhao, Alfarra, Rami, McFiggans, Gordon, Wiedensohler, Alfred, Kiendler-Scharr, Astrid, and Yuanhang Zhang

Abstract

As has been the case in North America and Western Europe, the SO2 emissions substantially reduced in North China Plain (NCP) in recent years. A dichotomy of reductions in SO2 and NOx concentrations result in the frequent occurrences of nitrate (pNO3−)-dominated particulate matter pollution over NCP. In this study, we observed a polluted episode with the nitrate mass fraction in non-refractory PM1 (NR-PM1) up to 44 % during wintertime in Beijing. Based on this typical pNO3−-dominated haze event, the linkage between aerosol water uptake and pNO3− formation, further impacting on visibility degradation, have been investigated based on field observations and theoretical calculations. During haze development, as ambient relative humidity (RH) increased from ~ 10 % up to 70 %, the aerosol particle liquid water increased from ~ 1 μg/m³ at the beginning to ~ 75 μg/m³ at the fully-developed haze period. Without considering the water uptake, the particle surface area and the volume concentrations increased by a factor of 4.1 and 4.8, respectively, during the development of haze event. Taking water uptake into account, the wet particle surface area and volume concentrations enhanced by a factor of 4.7 and 5.8, respectively. As a consequence, the hygroscopic growth of particles facilitated the condensational loss of dinitrogen pentoxide (N2O5) and nitric acid (HNO3) to particles contributing pNO3−. From the beginning to the fully-developed haze, the condensational loss of N2O5 increased by a factor of 20 when only considering aerosol surface area and volume of dry particles, while increasing by a factor of 25 considering extra surface area and volume due to water uptake. Similarly, the condensational loss of HNO3 increased by a factor of 2.7~2.9 and 3.1~3.5 for dry and wet aerosol surface area and volume from the beginning to the fully-developed haze period. Above results demonstrated that the pNO3− formation is further enhanced by aerosol water uptake with elevated ambient RH during haze development, in turn, facilitating the aerosol taking up water due to the hygroscopicity of nitrate salt. Such mutual promotion effect between aerosol particle liquid water and nitrate formation can rapidly degrade air quality and halve visibility within one day. Reduction of nitrogen-containing gaseous precursors, e.g., by control of traffic emissions, is essential in mitigating severe haze events in NCP. [ABSTRACT FROM AUTHOR]

Published

2019

17. Laboratory and field evaluation of the Aerosol Dynamics Inc. concentrator (ADIc) for aerosol mass spectrometry.

Author

Saarikoski, Sanna, Williams, Leah R., Spielman, Steven R., Lewis, Gregory S., Eiguren-Fernandez, Arantzazu, Aurela, Minna, Hering, Susanne V., Teinilä, Kimmo, Croteau, Philip, Jayne, John T., Hohaus, Thorsten, Worsnop, Douglas R., and Timonen, Hilkka

Subjects

SOLAR concentrators, LENSES, AEROSOLS, MASS spectrometry

Abstract

An air-to-air ultrafine particle concentrator (Aerosol Dynamics Inc. concentrator; ADIc) has been designed to enhance online chemical characterization of ambient aerosols using aerosol mass spectrometry. The ADIc employs a three-stage, moderated water-based condensation growth tube coupled to an aerodynamic focusing nozzle to concentrate fine particles into a portion of the flow. The system can be configured to sample between 1.0 and 1.7 L min -1 , with an output concentrated flow between 0.08 and 0.12 L min -1 , resulting in a theoretical concentration factor (sample flow / output flow) ranging from 8 to 21. Laboratory tests with monodisperse particles show that the ADIc is effective for particles as small as 10 nm. Laboratory experiments conducted with the Aerosol Mass Spectrometer (AMS) showed no shift in the particle size with the ADIc, as measured by the AMS particle time-of-flight operation. The ADIc-AMS system was operated unattended over a 1-month period near Boston, Massachusetts. Comparison to a parallel AMS without the concentrator showed concentration factors of 9.7±0.15 and 9.1±0.1 for sulfate and nitrate, respectively, when operated with a theoretical concentration factor of 10.5±0.3. The concentration factor of organics was lower, possibly due to the presence of large particles from nearby road-paving operations and a difference in aerodynamic lens cutoff between the two AMS instruments. Another field deployment was carried out in Helsinki, Finland. Two ∼10 d measurement periods showed good correlation for the concentrations of organics, sulfate, nitrate and ammonium measured with an Aerosol Chemical Speciation Monitor (ACSM) with the ADIc and a parallel AMS without the concentrator. Additional experiments with an AMS alternating between the ADIc and a bypass line demonstrated that the concentrator did not significantly change the size distribution or the chemistry of the ambient aerosol particles. [ABSTRACT FROM AUTHOR]

Published

2019

18. Gas-to-particle partitioning of major biogenic oxidation products: a study on freshly formed and aged biogenic SOA.

Author

Gkatzelis, Georgios I., Hohaus, Thorsten, Tillmann, Ralf, Gensch, Iulia, Müller, Markus, Eichler, Philipp, Xu, Kang-Ming, Schlag, Patrick, Schmitt, Sebastian H., Yu, Zhujun, Wegener, Robert, Kaminski, Martin, Holzinger, Rupert, Wisthaler, Armin, and Kiendler-Scharr, Astrid

Subjects

AIR quality, THERMAL desorption, ATMOSPHERIC aerosols, ORGANIC compounds, CLIMATE change

Abstract

Secondary organic aerosols (SOAs) play a key role in climate change and air quality. Determining the fundamental parameters that distribute organic compounds between the phases is essential, as atmospheric lifetime and impacts change drastically between the gas and particle phase. In this work, gas-to-particle partitioning of major biogenic oxidation products was investigated using three different aerosol chemical characterization techniques. The aerosol collection module, the collection thermal desorption unit, and the chemical analysis of aerosols online are different aerosol sampling inlets connected to a proton-transfer reaction time-of-flight mass spectrometer (ACM-PTR-ToF-MS, TD-PTR-ToF-MS, and CHARON-PTR-ToF-MS, respectively, referred to hereafter as ACM, TD, and CHARON). These techniques were deployed at the atmosphere simulation chamber SAPHIR to perform experiments on the SOA formation and aging from different monoterpenes (β-pinene, limonene) and real plant emissions (Pinus sylvestris L.). The saturation mass concentration C* and thus the volatility of the individual ions was determined based on the simultaneous measurement of their signal in the gas and particle phase. A method to identify and exclude ions affected by thermal dissociation during desorption and ionic dissociation in the ionization chamber of the proton-transfer reaction mass spectrometer (PTR-MS) was developed and tested for each technique. Narrow volatility distributions with organic compounds in the semi-volatile (SVOCs -- semi-volatile organic compounds) to intermediate-volatility (IVOCs -- intermediate-volatility organic compounds) regime were found for all systems studied. Despite significant differences in the aerosol collection and desorption methods of the proton-transfer-reaction (PTR)-based techniques, a comparison of the C* values obtained with different techniques was found to be in good agreement (within 1 order of magnitude) with deviations explained by the different operating conditions of the PTR-MS. The C* of the identified organic compounds were mapped onto the two-dimensional volatility basis set (2D-VBS), and results showed a decrease in C* with increasing oxidation state. For all experiments conducted in this study, identified partitioning organic compounds accounted for 20-30% of the total organic mass measured from an aerosol mass spectrometer (AMS). Further comparison between observations and theoretical calculations was performed for species found in our experiments that were also identified in previous publications. Theoretical calculations based on the molecular structure of the compounds showed, within the uncertainties ranges, good agreement with the experimental C* for most SVOCs, while IVOCs deviated by up to a factor of 300. These latter differences are discussed in relation to two main processes affecting these systems: (i) possible interferences by thermal and ionic fragmentation of higher molecularweight compounds, produced by accretion and oligomerization reactions, that fragment in the m/z range detected by the PTR-MS and (ii) kinetic influences in the distribution between the gas and particle phase with gas-phase condensation, diffusion in the particle phase, and irreversible uptake. [ABSTRACT FROM AUTHOR]

Published

2018

19. Comparison of three aerosol chemical characterization techniques utilizing PTR-ToF-MS: a study on freshly formed and aged biogenic SOA.

Author

Gkatzelis, Georgios I., Tillmann, Ralf, Hohaus, Thorsten, Müller, Markus, Eichler, Philipp, Xu, Kang-Ming, Schlag, Patrick, Schmitt, Sebastian H., Wegener, Robert, Kaminski, Martin, Holzinger, Rupert, Wisthaler, Armin, and Kiendler-Scharr, Astrid

Subjects

ATMOSPHERIC aerosols sampling, TIME-of-flight mass spectrometry, THERMAL desorption, PARTICLE size distribution, PHOTOCHEMISTRY, THERMODYNAMICS

Abstract

An intercomparison of different aerosol chemical characterization techniques has been performed as part of a chamber study of biogenic secondary organic aerosol (BSOA) formation and aging at the atmosphere simulation chamber SAPHIR (Simulation of Atmospheric PHotochemistry In a large Reaction chamber). Three different aerosol sampling techniques - the aerosol collection module (ACM), the chemical analysis of aerosol online (CHARON) and the collection thermal-desorption unit (TD) were connected to proton transfer reaction time-of-flight mass spectrometers (PTR-ToF-MSs) to provide chemical characterization of the SOA. The techniques were compared among each other and to results from an aerosol mass spectrometer (AMS) and a scanning mobility particle sizer (SMPS). The experiments investigated SOA formation from the ozonolysis of β-pinene, limonene, a β-pinene-limonene mix and real plant emissions from Pinus sylvestris L. (Scots pine). The SOA was subsequently aged by photo-oxidation, except for limonene SOA, which was aged by NO3 oxidation. Despite significant differences in the aerosol collection and desorption methods of the PTR-based techniques, the determined chemical composition, i.e. the same major contributing signals, was found by all instruments for the different chemical systems studied. These signals could be attributed to known products expected from the oxidation of the examined monoterpenes. The sampling and desorption method of ACM and TD provided additional information on the volatility of individual compounds and showed relatively good agreement. Averaged over all experiments, the total aerosol mass recovery compared to an SMPS varied within 80±10, 51±5 and 27±3% for CHARON, ACM and TD, respectively. Comparison to the oxygen-to-carbon ratios (O : C) obtained by AMS showed that all PTR-based techniques observed lower O: C ratios, indicating a loss of molecular oxygen either during aerosol sampling or detection. The differences in total mass recovery and O: C between the three instruments resulted predominantly from differences in the field strength (E=N) in the drift tube reaction ionization chambers of the PTR-ToF-MS instruments and from dissimilarities in the collection/desorption of aerosols. Laboratory case studies showed that PTR-ToF-MS E=N conditions influenced fragmentation which resulted in water and further neutral fragment losses of the detected molecules. Since ACM and TD were operated in higher E=N than CHARON, this resulted in higher fragmentation, thus affecting primarily the detected oxygen and carbon content and therefore also the mass recovery. Overall, these techniques have been shown to provide valuable insight on the chemical characteristics of BSOA and can address unknown thermodynamic properties such as partitioning coefficient values and volatility patterns down to a compound-specific level. [ABSTRACT FROM AUTHOR]

Published

2018

20. Gas-to-particle partitioning of major biogenic oxidation products from monoterpenes and real plant emissions.

Author

Gkatzelis, Georgios I., Hohaus, Thorsten, Tillmann, Ralf, Gensch, Iulia, Müller, Markus, Eichler, Philipp, Kang-Ming Xu, Schlag, Patrick, Schmitt, Sebastian H., Zhujun Yu, Wegener, Robert, Kaminski, Martin, Holzinger, Rupert, Wisthaler, Armin, and Kiendler-Scharr, Astrid

Abstract

Secondary organic aerosols (SOA) play a key role in climate change and air quality. Determining the fundamental parameters that distribute organic compounds between the phases is essential, as atmospheric lifetime and impacts change drastically between gas- and particle-phase. In this work, gas-to-particle partitioning of major biogenic oxidation products was investigated using three different aerosol chemical characterization techniques. The aerosol collection module (ACM), the collection thermal desorption unit (TD) and the chemical analysis of aerosol on-line (CHARON) are different aerosol sampling inlets connected to a Proton Transfer Reaction-Time-of-Flight-Mass Spectrometer (PTR-ToF-MS). These techniques were deployed at the atmosphere simulation chamber SAPHIR to perform experiments on the SOA formation and aging from different monoterpenes (β-pinene, limonene) and real plant emissions (Pinus sylvestris L.). The saturation mass concentration C* and thus the volatility of the individual ions was determined based on the simultaneous measurement of their signal in the gas- and particle-phase. A method to identify and exclude ions affected by thermal dissociation during desorption and ionic dissociation in the ionization chamber of the PTR-MS was developed and tested for each technique. Narrow volatility distributions with organic compounds in the semi-volatile (SVOCs) to intermediate volatility (IVOCs) regime were found for all systems studied. Despite significant differences in the aerosol collection and desorption methods of the PTR based techniques, comparison of the C* values obtained with different techniques were found to be in good agreement (within 1 order of magnitude) with deviations explained by the different operating conditions of the PTRMS. The C* of the identified organic compounds were mapped onto the 2-dimensional volatility basis set (2D-VBS) and results showed a decrease of the C* with increasing oxidation state. For all experiments conducted in this study, identified partitioning organic compounds accounted for 20–30 % of the total organic mass measured from an AMS. Further comparison between observations and theoretical calculations was performed for species found in our experiments that were also identified in previous publications. Theoretical calculations based on the molecular structure of the compounds showed, within the uncertainties ranges, good agreement with the experimental C* for most SVOCs, while IVOCs deviated up to a factor of 300. These latter differences are discussed in relation to two main processes affecting these systems: (i) possible interferences by thermal and ionic fragmentation of higher molecular weight compounds, produced by accretion and oligomerization reactions, that fragment in the m / z range detected by the PTRMS and (ii) kinetic influences in the distribution between gas- and particle-phase with gas-phase condensation, diffusion in the particle-phase and irreversible uptake. [ABSTRACT FROM AUTHOR]

Published

2018

21. Comparison of three aerosol chemical characterization techniques utilizing PTR-ToF-MS: A study on freshly formed and aged biogenic SOA.

Author

Gkatzelis, Georgios I., Tillmann, Ralf, Hohaus, Thorsten, Müller, Markus, Eichler, Philipp, Kang-Ming Xu, Schlag, Patrick, Schmitt, Sebastian H., Wegener, Robert, Kaminski, Martin, Holzinger, Rupert, Wisthaler, Armin, and Kiendler-Scharr, Astrid

Subjects

ATMOSPHERIC aerosols, DESORPTION, TIME-of-flight mass spectrometry

Abstract

An inter-comparison of different aerosol chemical characterization techniques has been performed as part of a chamber study of biogenic SOA formation and aging at the atmosphere simulation chamber SAPHIR. Three different aerosol sampling techniques, the aerosol collection module (ACM), the chemical analysis of aerosol on-line (CHARON) and the collection thermal desorption unit (TD) were connected to Proton Transfer Reaction Time of Flight Mass Spectrometers (PTR-ToF-MS) to provide chemical characterization of the SOA. The techniques were compared among each other and to results from an Aerosol Mass Spectrometer (AMS) and a Scanning Mobility Particle Sizer (SMPS). The experiments investigated SOA formation from the ozonolysis of β-pinene, limonene, a β-pinene/limonene mix and real plant emissions from Pinus sylvestris L. (Scots pine). The SOA was subsequently aged by photooxidation except for limonene SOA which was aged by NO3 oxidation. Despite significant differences in the aerosol collection and desorption methods of the PTR based techniques, the determined chemical composition, i.e. the same major contributing signals were found by all instruments for the different chemical systems studied. These signals could be attributed to known products expected from the oxidation of the examined monoterpenes. The sampling and desorption method of ACM and TD, provided additional information on the volatility of individual compounds and showed relatively good agreement. Averaged over all experiments, the total aerosol mass recovery compared to an SMPS varied from 80 ± 10 %, 51 ± 5 % and 27 ± 3 % for CHARON, ACM and TD, respectively. Comparison to the oxygen to carbon ratios (O : C) obtained by AMS showed that all PTR based techniques observed lower O : C ratios indicating a loss of molecular oxygen either during aerosol sampling or detection. The differences in total mass recovery and O : C between the three instruments resulted predominately from differences in the field strength (E/N) in the drift-tube reaction ionization chambers of the PTR-ToF-MS instruments and from dissimilarities in the collection/desorption of aerosols. Laboratory case studies showed that PTR-ToF-MS E/N conditions influenced fragmentation which resulted in water loss and carbon-oxygen bond breakage of the detected molecules. Since ACM and TD were operated in higher E/N compared to CHARON this resulted to higher fragmentation, thus affecting primarily the detected oxygen and carbon content and therefore also the mass recovery. Overall, these techniques have been shown to provide valuable insight on the chemical characteristics of BSOA, and can address unknown thermodynamic properties such as partitioning coefficient values and volatility patterns down to a compound specific level. [ABSTRACT FROM AUTHOR]

Published

2017

22. Annual cycle, seasonality and vertical distribution of aerosol optical and chemical properties observed at a continental site inWestern Europe.

Author

de Faria, Julia Perim, Schmitt, Sebastian, Bundke, Ulrich, Hohaus, Thorsten, Turdziladze, Avtandil, Mentel, Thomas, Defeng Zhao, Freedman, Andrew, Onasch, Timothy B., Kiendler-Scharr, Astrid, and Petzold, Andreas

Published

2018

23. Insights into PM1 during haze episodes in Beijing, China, using an aerosol mass spectrometer in a two-month winter field campaign 2016.

Author

Schmitt, Sebastian H., Schlag, Patrick, Gkatzelis, Georgios I., Hohaus, Thorsten, Mengren Li, Yu Wang, Dongjie Shang, Min Hu, Keding Lu, Yuanhang Zhang, Wahner, Andreas, and Kiendler-Scharr, Astrid

Published

2018