1996
DOI: 10.1088/0953-4075/29/21/009
|View full text |Cite
|
Sign up to set email alerts
|

Thermal stability of fullerenes: a shock tube study on the pyrolysis of and

Abstract: The thermal stability of fullerenes and dispersed in Ar was studied behind shock waves by following the time-dependent absorption and emission of the proposed decomposition product . The gas - particle mixtures filled into the shock tube were heated to temperatures at pressures of . Because of the relatively high vapour pressure of the fullerenes, they evaporate in a few microseconds so that both and are in the gas phase during most of the observation time. concentration profiles were measured by a ring … Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
2
1
1
1

Citation Types

0
15
0

Year Published

1998
1998
2021
2021

Publication Types

Select...
8
1

Relationship

0
9

Authors

Journals

citations
Cited by 32 publications
(15 citation statements)
references
References 20 publications
0
15
0
Order By: Relevance
“…Elimination of C 2 molecules from buckminsterfullerene is associated with genuinely high energy barriers since its cage possesses such a strong, rigid framework (the original motivation for Buckminster Fuller to create lightweight yet very stable large dome structures). The high temperatures required for pyrolytic decomposition of I h -C 60 (2,650 K) and D 5h -C 70 (2,440 K) [131] demonstrate that these cages, once formed, are extremely hard to destroy. The Stone-Wales transformation for I h -C 60 with barriers of 6-8 eV (depending on the choice of the DFT method) requires a temperature exceeding 1,100 K [132], and it can be assumed that, once a perfect I h -C 60 cage was obtained by the combination of C 2 elimination and Stone-Wales transformations, no more structural transformations should occur below this temperature.…”
Section: The "Shrinking Hot Giant" Road Of Fullerene Formationmentioning
confidence: 99%
“…Elimination of C 2 molecules from buckminsterfullerene is associated with genuinely high energy barriers since its cage possesses such a strong, rigid framework (the original motivation for Buckminster Fuller to create lightweight yet very stable large dome structures). The high temperatures required for pyrolytic decomposition of I h -C 60 (2,650 K) and D 5h -C 70 (2,440 K) [131] demonstrate that these cages, once formed, are extremely hard to destroy. The Stone-Wales transformation for I h -C 60 with barriers of 6-8 eV (depending on the choice of the DFT method) requires a temperature exceeding 1,100 K [132], and it can be assumed that, once a perfect I h -C 60 cage was obtained by the combination of C 2 elimination and Stone-Wales transformations, no more structural transformations should occur below this temperature.…”
Section: The "Shrinking Hot Giant" Road Of Fullerene Formationmentioning
confidence: 99%
“…Even higher maximum boundaries of thermal stability for fullerenes have been indicated. For example, the decomposition of C 60 and C 70 molecules in the gas phase has been pointed out to begin at 2650 and 2440 K, respectively [25]. In addition, one carbon atom in the C 60 fullerene connects with the other carbon atom with sp 2 hybridization bonds to form the delocalizationconjugated π bonds that can be broken down by argon ion bombardment [26].…”
Section: Deposition Mechanismmentioning
confidence: 99%
“…While it is known that fragmentation of the cage can be induced by pyrolysis [26] laser-irradiation [27] or collisions with charged/neutral particles [28][29][30], the mechanism of formation has remained unclear [31,32]. The processes of thermal fragmentation and reassembly of fullerene molecules in the gas phase has been recently reconsidered [25].…”
Section: Fragmentation and Reassembly Of Fullerenesmentioning
confidence: 99%