Your search keyword '"Jos Oomens"' showing total 6 results

1. On the electronic structure of isolated mono-dehydrogenated polyaromatic hydrocarbon ions and their astrophysical relevance

Author

Héctor Alvaro Galué, Jos Oomens, and Molecular Spectroscopy (HIMS, FNWI)

Subjects

Physics, Astrochemistry, Aryl, Infrared spectroscopy, Astronomy and Astrophysics, Electronic structure, Astrophysics::Cosmology and Extragalactic Astrophysics, Carbocation, Photochemistry, chemistry.chemical_compound, chemistry, Space and Planetary Science, Molecule, Singlet state, Atomic physics, Triplet state, Astrophysics::Galaxy Astrophysics

Abstract

The attribution of the unidentified infrared bands to polycyclic aromatic hydrocarbon (PAH) molecules is a key argument for their abundant occurrence in interstellar environments, which has important implications for interstellar chemistry. In contrast to terrestrial conditions, their transient forms are of importance in the low-density astrophysical environments. Here, the gas-phase IR spectra of three PAH molecules in a carbocation state (naphthyl+, C10H7 +; phenanthryl+, C14H9 +; and pyrenyl+, C16H9 +) are investigated by action spectroscopy methods using an infrared free electron laser and an ion-trap mass spectrometer. The IR spectra of the mono-dehydrogenated PAH+ (aryl) ions in the 6-18 μm spectral range are compared to computed IR spectra for various structural isomers of the aryl ions; the comparison indicates that the most stable structures under isolated conditions have a triplet electronic configuration. Electronic structure calculations on systems as large as the mono-dehydrogenated circumcoronene cation (C54H17 +) provide further evidence for the higher stability of a triplet state as compared with the singlet state. Moreover, the gas-phase IR spectra reveal that the IR signatures of a PAH cation before and after H-atom loss are very similar, in particular in the 6-9 μm region involving the skeletal CC stretching modes, so that triplet mono-dehydrogenated PAH ions are similarly compliant with the general match between PAH mid-IR features and the interstellar unidentified infrared emissions. The establishment of a triplet electronic ground state suggests that interstellar scenarios should consider the possible influence of triplet aromatic chemistry as well as the possible influence of the altered optical properties of triplet PAH species.

Published

2012

2. H2 ejection from polycyclic aromatic hydrocarbons: infrared multiphoton dissociation study of protonated acenaphthene and 9,10-dihydrophenanthrene

Author

Jos Oomens, Jeffrey D. Steill, Martin Vala, Jan Szczepanski, and Molecular Spectroscopy (HIMS, FNWI)

Subjects

Physics, Astrochemistry, Acenaphthene, Infrared spectroscopy, Astronomy and Astrophysics, Mass spectrometry, Dissociation (chemistry), chemistry.chemical_compound, chemistry, Space and Planetary Science, Excited state, Proton affinity, Physical chemistry, Infrared multiphoton dissociation, Atomic physics

Abstract

The infrared multiple-photon dissociation ( IRMPD) spectra of protonated acenaphthene ([ACN+H](+)) and 9,10-dihydrophenanthrene ([DHP+H](+)) have been recorded using an infrared free electron laser after the compounds were protonated by electrospray ionization and trapped in a Fourier transform ion cyclotron mass spectrometer. In both compounds, the loss of two mass units is predominant. Density functional calculations (B3LYP/6-311++G(d,p)) of the infrared spectra of all possible protonated isomers of each species showed that the observed IRMPD spectra are best fit to the isomer with the largest proton affinity and lowest relative electronic energy. Potential energy surfaces of the most stable isomers of [ACN+H](+) and [DHP+H](+) have been calculated for H and H-2 loss. The lowest energy barriers are for loss of H-2, with predicted energies 4.28 and 4.15 eV, respectively. After H-2 ejection, the adjacent aliphatic hydrogens migrate to the bare ejection site and stabilize the remaining fragment. Single H loss may occur from [ACN+H](+) but the energy required is higher. No single H loss is predicted from [DHP+H](+), only H migration around the carbon skeleton. The vibrational bands in the parent closed-shell protonated polycyclic aromatic hydrocarbons are compared to bands observed from the interstellar medium.

Published

2011

3. The Sequence of Coronene Hydrogenation Revealed by Gas-phase IR Spectroscopy.

Author

Stephanie Cazaux, Yann Arribard, Dmitrii Egorov, Julianna Palotás, Ronnie Hoekstra, Giel Berden, Jos Oomens, and Thomas Schlathölter

Subjects

MASS spectrometers, FREE electron lasers, HYDROGENATION, MASS spectrometry, ODD numbers, HYDROGEN atom

Abstract

Gas-phase coronene cations () can be sequentially hydrogenated with up to 24 additional H atoms, inducing a gradual transition from a planar, aromatic molecule toward a corrugated, aliphatic species. The mass spectra of hydrogenated coronene cations show that molecules with odd numbers of additional hydrogen atoms (nH) are dominant, with particularly high relative intensity for “magic numbers” nH = 5, 11, and 17, for which hydrogen atoms have the highest binding energies. Reaction barriers and binding energies strongly affect the hydrogenation sequence and its site specificity. In this contribution, we monitor this sequence experimentally by the evolution of infrared multiple-photon dissociation (IRMPD) spectra of gaseous with nH = 3–11, obtained using an infrared free electron laser coupled to a Fourier transform ion cyclotron mass spectrometer. For weakly hydrogenated systems (nH = 3, 5) multiple-photon absorption mainly leads to loss of H atoms (and/or H2). With increasing nH, C2H2 loss becomes more relevant. For nH = 9, 11, the carbon skeleton is substantially weakened and fragmentation is distributed over a large number of channels. A comparison of our IRMPD spectra with density functional theory calculations clearly shows that only one or two hydrogenation isomers contribute to each nH. This confirms the concept of hydrogenation occurring along very specific sequences. Moreover, the atomic sites participating in the first 11 steps of this hydrogenation sequence are clearly identified. [ABSTRACT FROM AUTHOR]

Published

2019

4. HIGH-RESOLUTION IR ABSORPTION SPECTROSCOPY OF POLYCYCLIC AROMATIC HYDROCARBONS IN THE 3 μm REGION: ROLE OF PERIPHERY.

Author

Elena Maltseva, Annemieke Petrignani, Alessandra Candian, Cameron J. Mackie, Xinchuan Huang, Timothy J. Lee, Alexander G. G. M. Tielens, Jos Oomens, and Wybren Jan Buma

Subjects

INFRARED absorption, AROMATIC compounds spectra, POLYCYCLIC aromatic hydrocarbons, ABSORPTION spectra, CHRYSENE, ACENES

Abstract

In this work we report on high-resolution IR absorption studies that provide a detailed view on how the peripheral structure of irregular polycyclic aromatic hydrocarbons (PAHs) affects the shape and position of their 3 μm absorption band. For this purpose, we present mass-selected, high-resolution absorption spectra of cold and isolated phenanthrene, pyrene, benz[a]antracene, chrysene, triphenylene, and perylene molecules in the 2950–3150 cm−1 range. The experimental spectra are compared with standard harmonic calculations and anharmonic calculations using a modified version of the SPECTRO program that incorporates a Fermi resonance treatment utilizing intensity redistribution. We show that the 3 μm region is dominated by the effects of anharmonicity, resulting in many more bands than would have been expected in a purely harmonic approximation. Importantly, we find that anharmonic spectra as calculated by SPECTRO are in good agreement with the experimental spectra. Together with previously reported high-resolution spectra of linear acenes, the present spectra provide us with an extensive data set of spectra of PAHs with a varying number of aromatic rings, with geometries that range from open to highly condensed structures, and featuring CH groups in all possible edge configurations. We discuss the astrophysical implications of the comparison of these spectra on the interpretation of the appearance of the aromatic infrared 3 μm band, and on features such as the two-component emission character of this band and the 3 μm emission plateau. [ABSTRACT FROM AUTHOR]

Published

2016

5. ERRATUM: “HIGH-RESOLUTION IR ABSORPTION SPECTROSCOPY OF POLYCYCLIC AROMATIC HYDROCARBONS: THE REALM OF ANHARMONICITY” (2015, ApJ, 814, 23).

Author

Elena Maltseva, Annemieke Petrignani, Alessandra Candian, Cameron J. Mackie, Xinchuan Huang, Timothy J. Lee, Alexander G. G. M. Tielens, Jos Oomens, and Wybren Jan Buma

Subjects

POLYCYCLIC aromatic hydrocarbons, ABSORPTION spectra

Abstract

A correction to the article "High-Resolution IR Absorption Spectroscopy of Polycyclic Aromatic Hydrocarbons: The Realm of Anharmonicity" that was published in the previous issue, is presented.

Published

2016

6. HIGH-RESOLUTION IR ABSORPTION SPECTROSCOPY OF POLYCYCLIC AROMATIC HYDROCARBONS: THE REALM OF ANHARMONICITY.

Author

Elena Maltseva, Annemieke Petrignani, Alessandra Candian, Cameron J. Mackie, Xinchuan Huang, Timothy J. Lee, Alexander G. G. M. Tielens, Jos Oomens, and Wybren Jan Buma

Subjects

HYDROCARBONS, ORGANIC compounds, DESORPTION, SORPTION, ADSORPTION hysteresis

Abstract

We report on an experimental and theoretical investigation of the importance of anharmonicity in the 3-μm CH stretching region of polycyclic aromatic hydrocarbon (PAH) molecules. We present mass-resolved, high-resolution spectra of the gas-phase cold (∼4 K) linear PAH molecules naphthalene, anthracene, and tetracene. The measured IR spectra show a surprisingly high number of strong vibrational bands. For naphthalene, the observed bands are well separated and limited by the rotational contour, revealing the band symmetries. Comparisons are made to the harmonic and anharmonic approaches of the widely used Gaussian software. We also present calculated spectra of these acenes using the computational program SPECTRO, providing anharmonic predictions with a Fermi-resonance treatment that utilizes intensity redistribution. We demonstrate that the anharmonicity of the investigated acenes is strong, dominated by Fermi resonances between the fundamental and double combination modes, with triple combination bands as possible candidates to resolve remaining discrepancies. The anharmonic spectra as calculated with SPECTRO lead to predictions of the main bands that fall within 0.5% of the experimental frequencies. The implications for the aromatic infrared bands, specifically the 3-μm band, are discussed. [ABSTRACT FROM AUTHOR]

Published

2015