Even–odd product variation of the Cn+ + D2 (n = 4–9) reaction: complexity of the linear carbon cation electronic states

Koyasu, Kiichirou; Ohtaki, T.; Ying.-Bing., Jiang; Takahashi, Kaito; Misaizu, Fuminori

doi:10.1039/c5cp04480d

Cited by 4 publications

(6 citation statements)

References 107 publications

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“…Third, linear clusters, if they do form through isomerization of cyclic clusters following their passage through the ion mobility spectrometer drift region -either when they were stored in the hexapole, passing through the octopole ion guide, or contained in the cryogenic QIT -would be expected to react rapidly with trace H 2 O or H 2 to form linear C n H + or HC n H + molecules. [5][6][7][8] We tested this by recording spectra of the C + n clusters with both H 2 /N 2 (100:1) and He/N 2 (100:1) buffer gas mixtures in the QIT and found no substantial differences in ToF mass spectra or in the electronic spectra. Last, preliminary experiments with mobility selection of the C + n clusters clearly show that the spectral features apparent in FIG.…”

Section: A Ion Mobility Datamentioning

confidence: 99%

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Buntine

Cotter

Jacovella

et al. 2021

The Journal of Chemical Physics

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Electronic spectra are measured for mass-selected C2n+(n = 6–14) clusters over the visible and near-infrared spectral range through resonance enhanced photodissociation of clusters tagged with N2 molecules in a cryogenic ion trap. The carbon cluster cations are generated through laser ablation of a graphite disk and can be selected according to their collision cross section with He buffer gas and their mass prior to being trapped and spectroscopically probed. The data suggest that the C2n+(n = 6–14) clusters have monocyclic structures with bicyclic structures becoming more prevalent for C22+ and larger clusters. The C2n+ electronic spectra are dominated by an origin transition that shifts linearly to a longer wavelength with the number of carbon atoms and associated progressions involving excitation of ring deformation vibrational modes. Bands for C12+, C16+, C20+, C24+, and C28+ are relatively broad, possibly due to rapid non-radiative decay from the excited state, whereas bands for C14+, C18+, C22+, and C26+ are narrower, consistent with slower non-radiative deactivation.

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Section: A Ion Mobility Datamentioning

confidence: 99%

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Buntine

Cotter

Jacovella

et al. 2021

The Journal of Chemical Physics

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“…Our result for the chain structures of the odd n is in agreement with the previous systematic study for C n H – , and in particular for n = 3, electronic energy differences between the lowest energy states of C 3 H – isomers are consistent with the previous studies. , For the cyclic geometries, we could not locate a transition state from the C n – + H 2 reactant. Thus, we consider the reaction path for forming C n H 2 – or C n H – by a single collision process where the H 2 approaches the edge carbon atom having the radical electron, similar to the case of C n + …”

Section: Resultsmentioning

confidence: 99%

“…This is opposite to the case of C n + linear chain. 6 These rate coefficients are obtained under the establishment of an equilibrium between the reactants and the TS. In some astrochemical environment where the concentration of surrounding gases is very low, this condition may not be satisfied.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Recently, carbon cluster cation C n + linear chain was reported to exhibit a size-dependent reactivity that odd number C n + has higher reactivity with D 2 compared to even ones, while the reaction rate decreases with increasing the cluster size. 6 In addition, a unique dissociation reaction path was reported for double charged carbon hydride system C 2 H 2 2+ , 7 and the mechanism was described by complex transition states and intermediate molecular states. On the other hand, the chemical property of carbon cluster anion C n − has been also investigated due to its interest in astrochemistry and astrophysics.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Small neutral as well as charged carbon chain clusters show complex reactivity associated with their geometrical property. Recently, carbon cluster cation C n + linear chain was reported to exhibit a size-dependent reactivity that odd number C n + has higher reactivity with D 2 compared to even ones, while the reaction rate decreases with increasing the cluster size . In addition, a unique dissociation reaction path was reported for double charged carbon hydride system C 2 H 2 2+ , and the mechanism was described by complex transition states and intermediate molecular states.…”

Section: Introductionmentioning

confidence: 99%

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Odd–Even Reactivity Variation Due to Dynamical Effects around the Roaming Saddle Points of the Reaction Between C_n^– Chain (n = 2–8) and H₂

Yoshida

Takahashi

2019

J. Phys. Chem. A

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Unsaturated carbon cluster chains often have chemical properties depending on the cluster size. While carbon cluster cation chains show odd–even variation in the reactivity with hydrogen, the chemistry of the carbon anion chain has been poorly understood even for the bimolecular reaction with hydrogen. We present a systematic theoretical study based on transition state calculations and molecular dynamics trajectory simulations for the reaction of C n – (n = 2–8) + H2. We show that carbon cluster chain anion also has an odd–even variation in reactivity where the even ones are more reactive. In addition, dynamics trajectory shows that while odd n only resulted in the C n H2 – product with direct H insertion similar to the static reaction pathway, even n had a more complex product branching producing not only C n H2 – but also C n H– + H and HC n H– with the roaming of an H atom. The flexibility of the carbon’s valence electrons plays an important role to form different isomers of the double H adducts HC n H– and C n H2 – from the roaming condition.

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A Short History of Cyclocarbons

Anderson

Patrick

Scriven

et al. 2020

Bulletin of the Chemical Society of Japan

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The cyclocarbons constitute a family of molecular carbon allotropes consisting of rings of two-coordinate atoms. Their high reactivities make them difficult to study, but there has been much progress towards understanding their structures and properties. Here we provide a short account of theoretical and experimental work on these carbon rings, and highlight opportunities for future research in this field.

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Even–odd product variation of the C_n⁺ + D₂ (n = 4–9) reaction: complexity of the linear carbon cation electronic states

Cited by 4 publications

References 107 publications

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Odd–Even Reactivity Variation Due to Dynamical Effects around the Roaming Saddle Points of the Reaction Between C_n^– Chain (n = 2–8) and H₂

A Short History of Cyclocarbons

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Even–odd product variation of the Cn+ + D2 (n = 4–9) reaction: complexity of the linear carbon cation electronic states

Cited by 4 publications

References 107 publications

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Electronic spectra of positively charged carbon clusters—C2n+ (n = 6–14)

Odd–Even Reactivity Variation Due to Dynamical Effects around the Roaming Saddle Points of the Reaction Between Cn– Chain (n = 2–8) and H2

A Short History of Cyclocarbons

Contact Info

Product

Resources

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Even–odd product variation of the C_n⁺ + D₂ (n = 4–9) reaction: complexity of the linear carbon cation electronic states

Odd–Even Reactivity Variation Due to Dynamical Effects around the Roaming Saddle Points of the Reaction Between C_n^– Chain (n = 2–8) and H₂