Your search keyword '"Einhard Kleist"' showing total 3 results

1. Chemical characterisation of benzene oxidation products under high- and low-NOx conditions using chemical ionisation mass spectrometry

Author

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

Subjects

chemistry.chemical_classification, Atmospheric Science, 010504 meteorology & atmospheric sciences, Iodide, Analytical chemistry, chemistry.chemical_element, 010501 environmental sciences, 01 natural sciences, Nitrogen, Oxygen, chemistry.chemical_compound, chemistry, 13. Climate action, Oxidation state, Volatile organic compound, Benzene, Carbon, NOx, 0105 earth and related environmental 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 Julich Plant Atmosphere Chamber as part of a series of experiments examining benzene oxidation by OH under high- and low-NO x 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 C 12 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-NO x 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 (C 6 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-NO x 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-NO x conditions. Hierarchical cluster analysis finds four clusters, of which two describe photo-oxidation. Cluster 2 shows a negative dependency on the NO 2 / NO x 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 ( OS C ‾ ) 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 NO 2 / NO x ratio and so is likely to contain more NO 2 addition and peroxy-derived termination products. This cluster contains fewer fragmented species, as the average carbon number is higher and OS C ‾ 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, NO 2 / NO x perturbations, coupled with a priori knowledge, can provide insight into identification of potential functionality.

Published

2021

2. Formation of highly oxidized multifunctional compounds: autoxidation of peroxy radicals formed in the ozonolysis of alkenes – deduced from structure–product relationships

Author

J. Wildt, Matti P. Rissanen, Andreas Wahner, Mikael Ehn, Theo Kurtén, Iida Pullinen, Einhard Kleist, Thomas F. Mentel, Monika Springer, Department of Physics, and Department of Chemistry

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, SECONDARY ORGANIC AEROSOLS, Radical, ATMOSPHERIC AEROSOL NUCLEATION, ALPHA-PINENE, INITIAL STEPS, OXIDATION, 010402 general chemistry, Photochemistry, 114 Physical sciences, 01 natural sciences, Aldehyde, lcsh:Chemistry, chemistry.chemical_compound, PARTICLE FORMATION, ddc:550, Organic chemistry, Molecule, EMISSIONS, Isoprene, 0105 earth and related environmental sciences, ISOMERIZATION, chemistry.chemical_classification, GROWTH-RATES, Ozonolysis, Autoxidation, SULFURIC ACID-AMINE, 15. Life on land, lcsh:QC1-999, 0104 chemical sciences, chemistry, lcsh:QD1-999, 13. Climate action, Mass spectrum, Isomerization, lcsh:Physics

Abstract

It has been postulated that secondary organic particulate matter plays a pivotal role in the early growth of newly formed particles in forest areas. The recently detected class of extremely low volatile organic compounds (ELVOC) provides the missing organic vapors and possibly contributes a significant fraction to atmospheric SOA (secondary organic aerosol). The sequential rearrangement of peroxy radicals and subsequent O2 addition results in ELVOC which are highly oxidized multifunctional molecules (HOM). Key for efficiency of such HOM in early particle growth is that their formation is induced by one attack of the oxidant (here O3), followed by an autoxidation process involving molecular oxygen. Similar mechanisms were recently observed and predicted by quantum mechanical calculations e.g., for isoprene. To assess the atmospheric importance and therewith the potential generality, it is crucial to understand the formation pathway of HOM. To elucidate the formation path of HOM as well as necessary and sufficient structural prerequisites of their formation we studied homologous series of cycloalkenes in comparison to two monoterpenes. We were able to directly observe highly oxidized multifunctional peroxy radicals with 8 or 10 O atoms by an Atmospheric Pressure interface High Resolution Time of Flight Mass Spectrometer (APi-TOF-MS) equipped with a NO3−-chemical ionization (CI) source. In the case of O3 acting as an oxidant, the starting peroxy radical is formed on the so-called vinylhydroperoxide path. HOM peroxy radicals and their termination reactions with other peroxy radicals, including dimerization, allowed for analyzing the observed mass spectra and narrowing down the likely formation path. As consequence, we propose that HOM are multifunctional percarboxylic acids, with carbonyl, hydroperoxy, or hydroxy groups arising from the termination steps. We figured that aldehyde groups facilitate the initial rearrangement steps. In simple molecules like cycloalkenes, autoxidation was limited to both terminal C atoms and two further C atoms in the respective α positions. In more complex molecules containing tertiary H atoms or small, constrained rings, even higher oxidation degrees were possible, either by simple H shift of the tertiary H atom or by initialization of complex ring-opening reactions.

Published

2015

3. Suppression of new particle formation from monoterpene oxidation by NOx

Author

Thorsten Hoffmann, Monika Springer, Jürgen Wildt, Franz Rohrer, Einhard Kleist, Astrid Kiendler-Scharr, Mikael Ehn, Andreas Wahner, Yinon Rudich, Ralf Tillmann, S. Andres, P. Müsgen, and Thomas F. Mentel

Subjects

chemistry.chemical_classification, Atmospheric Science, 010504 meteorology & atmospheric sciences, Monoterpene, Radical, Photodissociation, 010501 environmental sciences, Rate-determining step, Photochemistry, 01 natural sciences, Organic compound, chemistry.chemical_compound, chemistry, 13. Climate action, Particle, Hydroxyl radical, NOx, 0105 earth and related environmental sciences

Abstract

The impact of nitrogen oxides (NOx = NO + NO2) on new particle formation (NPF) and on photochemical ozone production from real plant volatile organic compound (BVOC) emissions was studied in a laboratory setup. At high NOx conditions ([BVOC] / [NOx] < 7, [NOx] > 23 ppb) new particle formation was suppressed. Instead, photochemical ozone formation was observed resulting in higher hydroxyl radical (OH) and lower nitrogen monoxide (NO) concentrations. When [NO] was reduced back to levels below 1 ppb by OH reactions, NPF was observed. Adding high amounts of NOx caused NPF to be slowed by orders of magnitude compared to analogous experiments at low NOx conditions ([NOx] ~300 ppt), although OH concentrations were higher. Varying NO2 photolysis enabled showing that NO was responsible for suppression of NPF. This suggests that peroxy radicals are involved in NPF. The rates of NPF and photochemical ozone production were related by power law dependence with an exponent approaching −2. This exponent indicated that the overall peroxy radical concentration must have been similar when NPF occurred. Thus, permutation reactions of first-generation peroxy radicals cannot be the rate limiting step in NPF from monoterpene oxidation. It was concluded that permutation reactions of higher generation peroxy-radical-like intermediates limit the rate of new particle formation. In contrast to the strong effects on the particle numbers, the formation of particle mass was substantially less sensitive to NOx concentrations. If at all, yields were reduced by about an order of magnitude only at very high NOx concentrations.

Published

2014