Incorporation of helium, neon, argon, krypton, and xenon into fullerenes using high pressure

Saunders, Martin; Jiménez‐Vázquez, Hugo A.; Cross, R. J.; Mroczkowski, S.; Gross, Michael L.; Giblin, Daryl; Poreda, Robert J.

doi:10.1021/ja00084a089

Cited by 331 publications

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“…The results also demonstrate the feasibility of determining the extent of He incorporation from the FT-ICR mass spectral peak heights. The present measurements are in agreement with those obtained by the pyrolysis method [1][2][3]. Although limited in sensitivity, the mass spectral method is faster and easier than pyrolysis.…”

supporting

confidence: 90%

“…Neutral C 60 samples containing approximately 1% 3 He@C 60 and 4 He@C 60 were prepared by the labeling method, in the presence of KCN [1][2][3]23]. For comparison, C 60 (99.5% purity) was purchased from Aldrich (Milwaukee, WI).…”

Section: Samplesmentioning

confidence: 99%

“…Another technique for the preparation of endohedral fullerene compounds is that of ion implantation (the endohedral species is neutralized on implantation). Endohedral species containing lithium and other alkali metals [15][16][17], the noble gases, He and Ne [18], and nitrogen [19] have been produced by that method.Endohedral compounds of all the noble gases can be prepared by heating fullerenes under high noble gas pressure [1][2][3]20]. Initially, yields of incorporation were approximately 0.1% for He, Ne, Ar and Kr and 0.03% for Xe.…”

mentioning

confidence: 99%

“…In the above studies, the noble gases were detected and quantified by pyrolyzing the material to release the gas, which was detected in either a quadrupole mass spectrometer [1,3,25] or a linear time-of-flight mass spectrometer [24]. It is possible, with sufficient labeling, for the larger noble gas endohedral fullerenes to be detected in standard mass spectra [2]. However, that method is not suitable…”

mentioning

confidence: 99%

“…Endohedral compounds of all the noble gases can be prepared by heating fullerenes under high noble gas pressure [1][2][3]20]. Initially, yields of incorporation were approximately 0.1% for He, Ne, Ar and Kr and 0.03% for Xe.…”

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Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Cooper

Hendrickson

Marshall

et al. 2002

J. Am. Soc. Mass Spectrom.

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In this paper, we report negative ion microelectrospray Fourier-transform ion cyclotron resonance (FT-ICR) mass spectrometry of C 60 samples containing ϳ1% 3 He@C 60 or 4 He@C 60 . Resolving 3 He@C 60 Ϫ and 4 He@C 60 Ϫ from C 60 containing 3 or 4 13 C instead of 12 C atoms is technically challenging, because the target species are present in low relative abundance and are very close in mass. Nevertheless, we achieve baseline resolution of 3 He@C 60 Ϫ from 13 C 3 12 C 57 Ϫ and 4 He@C 60 Ϫ from 13 C 4 12 C 56 Ϫ in single-scan mass spectra obtained in broadband mode without preisolation of the ions of interest. The results constitute the first direct mass spectrometric observation of endohedral helium in a fullerene sample at this (low) level of incorporation. The results also demonstrate the feasibility of determining the extent of He incorporation from the FT-ICR mass spectral peak heights. The present measurements are in agreement with those obtained by the pyrolysis method [1][2][3]. Although limited in sensitivity, the mass spectral method is faster and easier than pyrolysis. [4]) were observed [5,6] soon after the discovery of buckminsterfullerene (C 60 ) [7]. Following the development of the Krätschmer-Huffman method for preparation of fullerenes [8] (an electrical discharge between graphite electrodes in the presence of 0.2 atm of He gas), Smalley and co-workers produced macroscopic quantities of endohedral metallofullerenes in laser vaporization experiments on graphite doped with metal salts [4]. Weiske et al. [9] observed helium within the fragments of C 60 ϩ following high-energy collisions between the cations and the noble gas. Shortly after, the full He@C 60 ϩ adduct was observed [10,11]. Endohedral neon and argon compounds have also been produced by that method [12][13][14]. Another technique for the preparation of endohedral fullerene compounds is that of ion implantation (the endohedral species is neutralized on implantation). Endohedral species containing lithium and other alkali metals [15][16][17], the noble gases, He and Ne [18], and nitrogen [19] have been produced by that method.Endohedral compounds of all the noble gases can be prepared by heating fullerenes under high noble gas pressure [1][2][3]20]. Initially, yields of incorporation were approximately 0.1% for He, Ne, Ar and Kr and 0.03% for Xe. Subsequent experiments showed that reiterations of the labeling procedure resulted in higher yields of incorporation (ϳ1%) [21]. 3 He@C 60 , an NMR-active molecule, has also been prepared by that method [21,22]. Recent results have shown that the presence of KCN catalyzes the incorporation of noble gas, giving higher yields of incorporation (ϳ1%) in a single labeling experiment [23]. It is also known that He is trapped inside fullerenes (at about 1 ppm of empty fullerene) prepared by the Krätschmer-Huffman procedure [1,8]. In a recent finding, it was shown that fullerenes extracted from the Allende and Murchison meteorites contained endohedral helium [24]. The 3 He/ 4 He ratio in those fullerenes ...

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confidence: 90%

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confidence: 99%

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Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Cooper

Hendrickson

Marshall

et al. 2002

J. Am. Soc. Mass Spectrom.

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Free and hindered rotations in endohedral C60 fullerene complexes

Hernández-Rojas

Ruiz

Bretón

et al. 1997

Int. J. Quant. Chem.

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Fullerenes

Taylor

2002

Kirk-Othmer Encyclopedia of Chemical Technology

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Fullerenes are closed cage carbon molecules C 2 n ( n ≥ 10) comprising a combination of n carbon atoms of sp 2 (trigonal) hybridisation arranged into 12 pentagons and ( n ‐ 20)/2 hexagons. They are sometimes referred to as the “third form of carbon” (after diamond and graphite). Unlike the other forms of carbon, fullerenes are soluble in many organic solvents and undergo a wide range of standard chemical reactions. They can be formed by various procedures, but most commonly by vaporization of graphite either by use of lasers or electric arc discharge in an inert atmosphere. They do not occur naturally because of their instability arising from fairly rapid air oxidation. For a given value of n , very many isomers (having a wide range of stabilities) are possible, the number increasing geometrically with increasing size of n . Only a few are isolable. The most abundant fullerene is the spherical I h isomer of C 60 (there are 1819 other isomers, all unstable), which has a diameter of ∼10.0 Å. The next most abundant is C 70 , which is shaped like a kiwi fruit, and fullerenes containing >70 atoms are known as higher fullerenes. The geodesic structure of the molecules led to C 60 being named as “Buckminsterfullerene” after R. Buckminsterfullerene who popularized the use of geodesic domes in building construction. This term, now rarely used, gave rise to the abbreviated “fullerenes” for describing the whole class of materials. Because of the curved surfaces of the fullerenes, the π‐electrons are poorly delocalized so that C 60 is not very aromatic and contains essentially 30 double bonds and 60 single bonds. The main chemical reactions of fullerenes are therefore additions, and because of the cage curvature and hybridization state of the carbons, they are strongly electron deficient, reactions with electron‐rich nucleophiles being especially favored. Many derivatives having electron‐donor groups attached to the cage are being investigated with regard to their photoinduced electron‐transfer properties with potential for conversion of light into electricity. The cages are able to enclose a wide variety of atoms and molecules and these incar‐ or endohedral fullerenes have properties that differ from those of the empty cages. Larger fullerenes can also incorporate smaller ones and these multiwall or “nested” fullerenes are known as “onions”. Very elongated cages are known as nanotubes, and are potentially the strongest known constructional materials. These may consist of either a single tube (single‐wall nanotube, SWNT) or numerous concentric tubes within each other (multiwall nanotubes, MWNT), and various elements and molecules have been incorporated inside these also. Aza phospha‐ and borafullerenes have one or more nitrogen, phosphorus, or boron atom, respectively, replacing the corresponding number of carbon atoms in the cage structure. Nanotubes containing both nitrogen and boron atoms are also known. Fullerenes may be joined together in various ways (eg, by the use of high pressure) to give polymeric structures, but these are difficult to process and analyse because of very low solubility. Some fullerenes with alkaline metals incorporated into the lattices show superconducting properties in the solid state, but they are pyrophoric. Although fullerenes are insoluble in water, some derivatives are very soluble and this has led to investigations of biological properties. In particular, their use in connection with removal of free radicals, anti‐ human immunodeficiency virus (HIV) properties, antiviral behavior, and photodynamic therapy are all under investigation.

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Incorporation of helium, neon, argon, krypton, and xenon into fullerenes using high pressure

Cited by 331 publications

References 0 publications

Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Free and hindered rotations in endohedral C60 fullerene complexes

Fullerenes

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Incorporation of helium, neon, argon, krypton, and xenon into fullerenes using high pressure

Cited by 331 publications

References 0 publications

Direct detection and quantitation of He@C60 by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Direct detection and quantitation of He@C60 by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Free and hindered rotations in endohedral C60 fullerene complexes

Fullerenes

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Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry

Direct detection and quantitation of He@C₆₀ by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry