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622 results on '"Dagaut, Philippe"'

1. Formation of Organic Acids and Carbonyl Compounds in n‐Butane Oxidation via γ‐Ketohydroperoxide Decomposition

Author

Popolan‐Vaida, Denisia M, Eskola, Arkke J, Rotavera, Brandon, Lockyear, Jessica F, Wang, Zhandong, Sarathy, S Mani, Caravan, Rebecca L, Zádor, Judit, Sheps, Leonid, Lucassen, Arnas, Moshammer, Kai, Dagaut, Philippe, Osborn, David L, Hansen, Nils, Leone, Stephen R, and Taatjes, Craig A

Subjects
Chemical Sciences, Autoignition, Hydrocarbon Oxidation, Ketohydroperoxides, Korcek Reaction, Photoionization, Organic Chemistry, Chemical sciences
Abstract

A crucial chain-branching step in autoignition is the decomposition of ketohydroperoxides (KHP) to form an oxy radical and OH. Other pathways compete with chain-branching, such as "Korcek" dissociation of γ-KHP to a carbonyl and an acid. Here we characterize the formation of a γ-KHP and its decomposition to formic acid+acetone products from observations of n-butane oxidation in two complementary experiments. In jet-stirred reactor measurements, KHP is observed above 590 K. The KHP concentration decreases with increasing temperature, whereas formic acid and acetone products increase. Observation of characteristic isotopologs acetone-d3 and formic acid-d0 in the oxidation of CH3 CD2 CD2 CH3 is consistent with a Korcek mechanism. In laser-initiated oxidation experiments of n-butane, formic acid and acetone are produced on the timescale of KHP removal. Modelling the time-resolved production of formic acid provides an estimated upper limit of 2 s-1 for the rate coefficient of KHP decomposition to formic acid+acetone.

Published
2022

11. A comprehensive experimental and kinetic modeling study of di-isobutylene isomers: Part 1

Author

Lokachari, Nitin, Kukkadapu, Goutham, Song, Hwasup, Vanhove, Guillaume, Lailliau, Maxence, Dayma, Guillaume, Serinyel, Zeynep, Zhang, Kuiwen, Dauphin, Roland, Etz, Brian, Kim, Seonah, Steglich, Mathias, Bodi, Andras, Fioroni, Gina, Hemberger, Patrick, Matveev, Sergey S., Konnov, Alexander A., Dagaut, Philippe, Wagnon, Scott W., Pitz, William J., and Curran, Henry J.

Published
2023
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12. Corrigendum to “A comprehensive experimental and modeling study of n-propylcyclohexane oxidation” [Combust. Flame 238 (2022) 111944]

Author

Liu, Mingxia, primary, Fang, Ruozhou, additional, Sung, Chih-Jen, additional, Aljohani, Khalid, additional, Farooq, Aamir, additional, Almarzooq, Yousef, additional, Mathieu, Olivier, additional, Petersen, Eric L., additional, Dagaut, Philippe, additional, Zhao, Jie, additional, Tao, Zhiping, additional, Yang, Lijun, additional, and Zhou, Chong-Wen, additional

Published
2024
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15. Tracking the reaction networks of acetaldehyde oxide and glyoxal oxide Criegee intermediates in the ozone-assisted oxidation reaction of crotonaldehyde.

Author

DeCecco, Alec C., Conrad, Alan R., Floyd, Arden M., Jasper, Ahren W., Hansen, Nils, Dagaut, Philippe, Moody, Nath-Eddy, and Popolan-Vaida, Denisia M.

Abstract

The reaction of unsaturated compounds with ozone (O3) is recognized to lead to the formation of Criegee intermediates (CIs), which play a key role in controlling the atmospheric budget of hydroxyl radicals and secondary organic aerosols. The reaction network of two CIs with different functionality, i.e. acetaldehyde oxide (CH3CHOO) and glyoxal oxide (CHOCHOO) formed in the ozone-assisted oxidation reaction of crotanaldehyde (CA), is investigated over a temperature range between 390 K and 840 K in an atmospheric pressure jet-stirred reactor (JSR) at a residence time of 1.3 s, stoichiometry of 0.5 with a mixture of 1% crotonaldehyde, 10% O2, at an fixed ozone concentration of 1000 ppm and 89% Ar dilution. Molecular-beam mass spectrometry in conjunction with single photon tunable synchrotron vacuum-ultraviolet (VUV) radiation is used to identify elusive intermediates by means of experimental photoionization energy scans and ab initio threshold energy calculations for isomer identification. Addition of ozone (1000 ppm) is observed to trigger the oxidation of CA already at 390 K, which is below the temperature where the oxidation reaction of CA was observed in the absence of ozone. The observed CA + O3 product, C4H6O4, is found to be linked to a ketohydroperoxide (2-hydroperoxy-3-oxobutanal) resulting from the isomerization of the primary ozonide. Products corresponding to the CIs uni- and bi-molecular reactions were observed and identified. A network of CI reactions is identified in the temperature region below 600 K, characterized by CIs bimolecular reactions with species like aldehydes, i.e., formaldehyde, acetaldehyde, and crotonaldehyde and alkenes, i.e., ethene and propene. The region below 600 K is also characterized by the formation of important amounts of typical low-temperature oxidation products, such as hydrogen peroxide (H2O2), methyl hydroperoxide (CH3OOH), and ethyl hydroperoxide (C2H5OOH). Detection of additional oxygenated species such as alcohols, ketene, and aldehydes are indicative of multiple active oxidation routes. This study provides important information about the initial step involved in the CIs assisted oligomerization reactions in complex reactive environments where CIs with different functionalities are reacting simultaneously. It provides new mechanistic insights into ozone-assisted oxidation reactions of unsaturated aldehydes, which is critical for the development of improved atmospheric and combustion kinetics models. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Unraveling the structure and chemical mechanisms of highly oxygenated intermediates in oxidation of organic compounds

Author

Wang, Zhandong, Popolan-Vaida, Denisia M, Chen, Bingjie, Moshammer, Kai, Mohamed, Samah Y, Wang, Heng, Sioud, Salim, Raji, Misjudeen A, Kohse-Höinghaus, Katharina, Hansen, Nils, Dagaut, Philippe, Leone, Stephen R, and Sarathy, S Mani

Subjects
Earth Sciences, Organic Chemistry, Chemical Sciences, autooxidation, peroxides, ignition, secondary organic aerosol, mass spectrometry
Abstract

Decades of research on the autooxidation of organic compounds have provided fundamental and practical insights into these processes; however, the structure of many key autooxidation intermediates and the reactions leading to their formation still remain unclear. This work provides additional experimental evidence that highly oxygenated intermediates with one or more hydroperoxy groups are prevalent in the autooxidation of various oxygenated (e.g., alcohol, aldehyde, keto compounds, ether, and ester) and nonoxygenated (e.g., normal alkane, branched alkane, and cycloalkane) organic compounds. These findings improve our understanding of autooxidation reaction mechanisms that are routinely used to predict fuel ignition and oxidative stability of liquid hydrocarbons, while also providing insights relevant to the formation mechanisms of tropospheric aerosol building blocks. The direct observation of highly oxygenated intermediates for the autooxidation of alkanes at 500-600 K builds upon prior observations made in atmospheric conditions for the autooxidation of terpenes and other unsaturated hydrocarbons; it shows that highly oxygenated intermediates are stable at conditions above room temperature. These results further reveal that highly oxygenated intermediates are not only accessible by chemical activation but also by thermal activation. Theoretical calculations on H-atom migration reactions are presented to rationalize the relationship between the organic compound's molecular structure (n-alkane, branched alkane, and cycloalkane) and its propensity to produce highly oxygenated intermediates via extensive autooxidation of hydroperoxyalkylperoxy radicals. Finally, detailed chemical kinetic simulations demonstrate the influence of these additional reaction pathways on the ignition of practical fuels.

Published
2017

23. New insights into the low-temperature oxidation of 2-methylhexane

Author

Wang, Zhandong, Mohamed, Samah Y, Zhang, Lidong, Moshammer, Kai, Popolan-Vaida, Denisia M, Shankar, Vijai Shankar Bhavani, Lucassen, Arnas, Ruwe, Lena, Hansen, Nils, Dagaut, Philippe, and Sarathy, S Mani

Subjects
Engineering, Mechanical Engineering, Automotive Engineering, Auto-oxidation, Highly oxidized multifunctional molecules, Peroxides, Alternative isomerization, Synchrotron VUV photoionization mass spectrometry, Chemical Engineering, Automotive engineering, Fluid mechanics and thermal engineering, Mechanical engineering
Abstract

The low-temperature oxidation of a stoichiometric 2-methylhexane/O2/Ar mixture was examined in a jet-stirred reactor coupled with synchrotron vacuum UV photoionization molecular-beam MS. Low-temperature oxidation intermediates with two to five oxygen atoms were observed. The detection of C7H14O5 and C7H14O4 species implies that a third O2 addition process occurred in 2-methylhexane low-temperature oxidation. A detailed kinetic model was developed to describes the third O2 addition and subsequent reactions leading to C7H14O5 (keto-dihydroperoxide and dihydroperoxy cyclic ether) and C7H14O4 (diketo-hydroperoxide and keto-hydroperoxy cyclic ether) species. The kinetics of the third O2 addition reactions revealed that the addition reactions promoted 2-methylhexane auto-ignition at low temperatures.

Published
2017

29. Quantification of the Keto-Hydroperoxide (HOOCH2OCHO) and Other Elusive Intermediates during Low-Temperature Oxidation of Dimethyl Ether

Author

Moshammer, Kai, Jasper, Ahren W, Popolan-Vaida, Denisia M, Wang, Zhandong, Shankar, Vijai Shankar Bhavani, Ruwe, Lena, Taatjes, Craig A, Dagaut, Philippe, and Hansen, Nils

Subjects
Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Physical Sciences, Atomic, Molecular and Optical Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Physical chemistry, Theoretical and computational chemistry, Atomic, molecular and optical physics
Abstract

This work provides new temperature-dependent mole fractions of elusive intermediates relevant to the low-temperature oxidation of dimethyl ether (DME). It extends the previous study of Moshammer et al. [ J. Phys. Chem. A 2015 , 119 , 7361 - 7374 ] in which a combination of a jet-stirred reactor and molecular beam mass spectrometry with single-photon ionization via tunable synchrotron-generated vacuum-ultraviolet radiation was used to identify (but not quantify) several highly oxygenated species. Here, temperature-dependent concentration profiles of 17 components were determined in the range of 450-1000 K and compared to up-to-date kinetic modeling results. Special emphasis is paid toward the validation and application of a theoretical method for predicting photoionization cross sections that are hard to obtain experimentally but essential to turn mass spectral data into mole fraction profiles. The presented approach enabled the quantification of the hydroperoxymethyl formate (HOOCH2OCH2O), which is a key intermediate in the low-temperature oxidation of DME. The quantification of this keto-hydroperoxide together with the temperature-dependent concentration profiles of other intermediates including H2O2, HCOOH, CH3OCHO, and CH3OOH reveals new opportunities for the development of a next-generation DME combustion chemistry mechanism.

Published
2016

30. Additional chain-branching pathways in the low-temperature oxidation of branched alkanes

Author

Wang, Zhandong, Zhang, Lidong, Moshammer, Kai, Popolan-Vaida, Denisia M, Shankar, Vijai Shankar Bhavani, Lucassen, Arnas, Hemken, Christian, Taatjes, Craig A, Leone, Stephen R, Kohse-Höinghaus, Katharina, Hansen, Nils, Dagaut, Philippe, and Sarathy, S Mani

Subjects
Engineering, Mechanical Engineering, Automotive Engineering, Auto-oxidation, Chain-branching, Highly oxidized multifunctional molecules, Peroxides, Alternative isomerization, Synchrotron VUV photoionization mass spectrometry, Chemical Engineering, Energy, Automotive engineering, Chemical engineering, Fluid mechanics and thermal engineering
Abstract

Chain-branching reactions represent a general motif in chemistry, encountered in atmospheric chemistry, combustion, polymerization, and photochemistry; the nature and amount of radicals generated by chain-branching are decisive for the reaction progress, its energy signature, and the time towards its completion. In this study, experimental evidence for two new types of chain-branching reactions is presented, based upon detection of highly oxidized multifunctional molecules (HOM) formed during the gas-phase low-temperature oxidation of a branched alkane under conditions relevant to combustion. The oxidation of 2,5-dimethylhexane (DMH) in a jet-stirred reactor (JSR) was studied using synchrotron vacuum ultra-violet photoionization molecular beam mass spectrometry (SVUV-PI-MBMS). Specifically, species with four and five oxygen atoms were probed, having molecular formulas of C8H14O4 (e.g., diketo-hydroperoxide/keto-hydroperoxy cyclic ether) and C8H16O5 (e.g., keto-dihydroperoxide/dihydroperoxy cyclic ether), respectively. The formation of C8H16O5 species involves alternative isomerization of OOQOOH radicals via intramolecular H-atom migration, followed by third O2 addition, intramolecular isomerization, and OH release; C8H14O4 species are proposed to result from subsequent reactions of C8H16O5 species. The mechanistic pathways involving these species are related to those proposed as a source of low-volatility highly oxygenated species in Earth's troposphere. At the higher temperatures relevant to auto-ignition, they can result in a net increase of hydroxyl radical production, so these are additional radical chain-branching pathways for ignition. The results presented herein extend the conceptual basis of reaction mechanisms used to predict the reaction behavior of ignition, and have implications on atmospheric gas-phase chemistry and the oxidative stability of organic substances.

Published
2016

31. Detection and Identification of the Keto-Hydroperoxide (HOOCH2OCHO) and Other Intermediates during Low-Temperature Oxidation of Dimethyl Ether

Author

Moshammer, Kai, Jasper, Ahren W, Popolan-Vaida, Denisia M, Lucassen, Arnas, Dievarti, Pascal, Selim, Hatem, Eskola, Arkke J, Taatjes, Craig A, Leone, Stephen R, Sarathy, S Mani, Ju, Yiguang, Dagaut, Philippe, Kohse-Hoeinghaus, Katharina, and Hansen, Nils

Subjects
Theoretical and Computational Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)
Published
2015

36. Influence of EGR compounds on the oxidation of an HCCI-diesel surrogate

Author

Anderlohr, Jörg, Piperel, A., Da Cruz, A. Pires, Bounaceur, Roda, Battin-Leclerc, Frédérique, Dagaut, Philippe, and Montagne, X.

Subjects
Physics - Chemical Physics
Abstract

This paper presents an experimental and numerical study of the impact of various additives on the oxidation of a typical automotive surrogate fuel blend, i.e. n-heptane and toluene. It examines the impact of engine re-cycled exhaust has compounds on the control of an Homogeneous Charge Compression-Ignition (HCCI) engine. Series of experiments were performed in a hihly diluted Jet-Stirred Reactor (JDR) at pressures of 1 and 10 atm (1 atm = 101,325 Pa). The chosen thermo-chemical conditions were close to those characteristices of the pre-ignition period in an HCCI engine. The influence of various additives, namely nitric oxide (NO), ethylene (C2H4) and methanol (CH3OH), on the oxidation of a n-heptane/toluene blend was studied over a wide range of temperatures (550-1100 K), including the zone of the Negative Temperature Coefficient (NTC).

Published
2009
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47. The first balloon-borne sample analysis of atmospheric carbonaceous components reveals new insights into formation processes

Author

Benoit, Roland, primary, Vernier, Hazel, additional, Vernier, Jean-Paul, additional, Joly, Lilian, additional, Dumelié, Nicolas, additional, Wienhold, Frank G., additional, Crevoisier, Cyril, additional, Delpeux, Sandrine, additional, Bernard, François, additional, Dagaut, Philippe, additional, and Berthet, Gwenaël, additional

Published
2023
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