Laboratory Photochemistry of Covalently Bonded Fluorene Clusters: Observation of an Interesting PAH Bowl-forming Mechanism

Zhang, Weiwei; Si, Yubing; Jiang, Zhen; Chen, Tao; Linnartz, H.; Tielens, A. G. G. M.

doi:10.3847/1538-4357/aafe10

Cited by 31 publications

(12 citation statements)

References 60 publications

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“…25 For this reason, several recent studies have been focusing on PAH pentagon formation schemes, to further exploit bowling mechanisms under interstellar conditions. 26,27 With the tenuous connection between PAHs and fullerenes in space, it is worth noting that fullerenes may contribute to the ionization balance of the ISM and the photoelectric heating of PDRs in a similar way as PAHs have been found to be. 28 In and of itself C 60 has been proposed as a diagnostic tool to estimate the temperature and/or UV flux inside molecular clouds 29 but such data is dependent on measurements of solid C 60 rather than gas-phase measurements as those relative to DIBs studies.…”

Section: Introductionmentioning

confidence: 98%

VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

Hróðmarsson

Garcia

Linnartz

et al. 2020

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 98%

VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

Hróðmarsson

Garcia

Linnartz

et al. 2020

Phys. Chem. Chem. Phys.

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“…Also, Carpentier et al (2012) found disordered, "fullerene-like structures" in soot particles emulating HACs, while Duley & Hu (2012) suggested the presence of "protofullerenes" in Raman spectra of HAC analogs, but neither experimental study claimed evidence of C 60 in their data. Laboratory work by Tielens and collaborators (e.g., Berné & Tielens 2012;Zhen et al 2014;Zhang et al 2019) suggests that PAHs may be a route to C 60 .…”

Section: Introductionmentioning

confidence: 99%

Formation of Interstellar C₆₀ from Silicon Carbide Circumstellar Grains

Bernal

Haenecour

Zega

et al. 2019

ApJL

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We have conducted laboratory experiments with analog crystalline silicon carbide (SiC) grains using transmission electron microscopy (TEM) and electron energy-loss spectroscopy (EELS). The 3C polytype of SiC was used-the type commonly produced in the envelopes of asymptotic giant branch (AGB) stars. We rapidly heated small (∼50 nm) synthetic SiC crystals under vacuum to ∼1300 K and bombarded them with 150 keV Xe ions. TEM imaging and EELS spectroscopic mapping show that such heating and bombardment leaches silicon from the SiC surface, creating layered graphitic sheets. Surface defects in the crystals were found to distort the six-membered rings characteristic of graphite, creating hemispherical structures with diameters matching that of C 60. Such nonplanar features require the formation of five-membered rings. We also identified a circumstellar grain, preserved inside the Murchison meteorite, that contains the remnant of an SiC core almost fully encased by graphite, contradicting long-standing thermodynamic predictions of material condensation. Our combined laboratory data suggest that C 60 can undergo facile formation from shock heating and ion bombardment of circumstellar SiC grains. Such heating/bombardment could occur in the protoplanetary nebula phase, accounting for the observation of C 60 in these objects, in planetary nebulae (PNs) and other interstellar sources receiving PN ejecta. The synthesis of C 60 in astronomical sources poses challenges, as the assembly of 60 pure carbon atoms in an H-rich environment is difficult. The formation of C 60 from the surface decomposition of SiC grains is a viable mechanism that could readily occur in the heterogeneous, hydrogen-dominated gas of evolved circumstellar shells.

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“…In our previous studies, we have reported laboratory experiments on van der Waals bonded, PAH clusters and their photochemical evolution towards large PAH molecules in a bottom-up process (Zhen et al 2018;Zhang et al 2019). Given the presence of C 60 in PDRs such as NGC 7023 (Sellgren et al 2010), studies of clusters involving C 60 have become of great interest as well.…”

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confidence: 99%

Laboratory Formation and Photochemistry of Fullerene/Anthracene Cluster Cations

Jiang

Zhang

Yang

et al. 2019

ApJ

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Besides buckminsterfullerene (C 60 ), other fullerenes and their derivatives may also reside in space.In this work, we study the formation and photo-dissociation processes of astronomically relevant fullerene/anthracene (C 14 H 10 ) cluster cations in the gas phase. Experiments are carried out using a quadrupole ion trap (QIT) in combination with time-of-flight (TOF) mass spectrometry. The results show that fullerene (C 60 , and C 70 )/anthracene (i.e., [(C 14 H 10 ) n C 60 ] + and [(C 14 H 10 ) n C 70 ] + ), fullerene (C 56 and C 58 )/anthracene (i.e., [(C 14 H 10 ) n C 56 ] + and [(C 14 H 10 ) n C 58 ] + ) and fullerene (C 66 and C 68 )/anthracene (i.e., [(C 14 H 10 ) n C 66 ] + and [(C 14 H 10 ) n C 68 ] + ) cluster cations, are formed in the gas phase through an ion-molecule reaction pathway. With irradiation, all the fullerene/anthracene cluster cations dissociate into mono−anthracene and fullerene species without dehydrogenation. The structure of newly formed fullerene/anthracene cluster cations and the bonding energy for these reaction pathways are investigated with quantum chemistry calculations.Our results provide a growth route towards large fullerene derivatives in a bottom-up process and insight in their photo-evolution behavior in the ISM, and clearly, when conditions are favorable, fullerene/PAH clusters can form efficiently. In addition, these clusters (from 80 to 154 atoms or ∼ 2 nm in size) offer a good model for understanding the physical-chemical processes involved in the formation and evolution of carbon dust grains in space, and provide candidates of interest for the DIBs that could motivate spectroscopic studies.

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Laboratory Photochemistry of Covalently Bonded Fluorene Clusters: Observation of an Interesting PAH Bowl-forming Mechanism

Cited by 31 publications

References 60 publications

VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

Formation of Interstellar C₆₀ from Silicon Carbide Circumstellar Grains

Laboratory Formation and Photochemistry of Fullerene/Anthracene Cluster Cations

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Laboratory Photochemistry of Covalently Bonded Fluorene Clusters: Observation of an Interesting PAH Bowl-forming Mechanism

Cited by 31 publications

References 60 publications

VUV photoionization dynamics of the C60 buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

VUV photoionization dynamics of the C60 buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

Formation of Interstellar C60 from Silicon Carbide Circumstellar Grains

Laboratory Formation and Photochemistry of Fullerene/Anthracene Cluster Cations

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VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

VUV photoionization dynamics of the C₆₀ buckminsterfullerene: 2D-matrix photoelectron spectroscopy in an astrophysical context

Formation of Interstellar C₆₀ from Silicon Carbide Circumstellar Grains