Intercalation of fullerite C60 with N2 molecules. An investigation by x-ray powder diffraction

Galtsov, N. N.; Prokhvatilov, A. I.; Dolgova, G.N.; Cassidy, David J.; Gadd, G. E.; Moricca, S.; Sundqvist, Bertil

doi:10.1063/1.2796156

Cited by 15 publications

(7 citation statements)

References 32 publications

(61 reference statements)

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“…The result of the investigations of the temperature dependence a͑T͒ in the solid solutions C 60 -O 2 as well as the published data for pure fullerite 24,26 are presented in Fig. The result of the investigations of the temperature dependence a͑T͒ in the solid solutions C 60 -O 2 as well as the published data for pure fullerite 24,26 are presented in Fig.…”

Section: Resultsmentioning

confidence: 90%

Effect of impurity oxygen molecules on the structural and thermodynamic properties of fullerite C60

Yagotintsev

Stetsenko

Galtsov

et al. 2010

Low Temperature Physics

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Articles you may be interested inEffect of nitrogen sorption mechanisms on the properties of fullerite C60 over a wide range of temperatures Low Temp. Phys. 40, 685 (2014); 10.1063/1.4894316 The effect of glass transition in fullerite C60 on Ar impurity diffusion Low Temp. Saturation of fullerite C60 with hydrogen: Adsorption crossover studies Low Temp. Phys. 38, 952 (2012); Fiz. Nizk. Temp. 36, 335-342 ͑March 2010͒Intercalation of fullerite C 60 with oxygen molecules is performed by two methods-under ordinary conditions of saturation at room temperature and gas pressure 1 atm as well as at elevated temperature ͑373 K͒ and pressure ͑10 atm͒. The time dependences of the lattice parameter of fullerite during intercalation are determined. This made it possible to evaluate the activation energy and the coefficient of diffusion of oxygen molecules in fullerite C 60 . It is shown that increasing the temperature and pressure of the gas increases the diffusion coefficient almost fivefold: from D Ϸ͑1.6Ϯ 1.9͒ ·10 −14 cm 2 / s at atmospheric pressure and room temperature to D Ϸ͑7.1Ϯ 1.9͒ ·10 −14 cm 2 / s for pressure P = 10 atm and temperature T = 373 K. The oxygen concentration in octahedral voids and the temperatures of phase transitions in solutions are determined on the basis of an analysis of the results obtained together with published data on the effect of atomic and molecular impurities on the properties of C 60 . The effect of oxygen impurity on the properties of an orientational phase transition and the temperature dependence of the lattice parameter is investigated.

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Section: Resultsmentioning

confidence: 90%

Effect of impurity oxygen molecules on the structural and thermodynamic properties of fullerite C60

Yagotintsev

Stetsenko

Galtsov

et al. 2010

Low Temperature Physics

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“…A typical HIP application is illustrated [4] by the intercalation of fullerite by inert gases such as Ar, Kr, and Xe where pressures of 170-220 MPa and temperatures of 200-500°C were used to produce intercalates Ar 1.0 C 60 , Kr 0.9 C 60 , and Xe 0.66 C 60 . Other applications of the HIP method may be found in a number of publications [5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23]. In this method, temperature and pressure cannot substantially exceed the values given above because an increase in pressure results in fullerene polymerization while an increase in temperature leads to reactions with small reactive species such as oxygen.…”

Section: Introductionmentioning

confidence: 96%

Synthesis and properties of C60 fullerite intercalated by acetylene

Shul’ga¹,

Мартыненко²,

Баскаков³

et al. 2009

Chemical Physics Letters

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“…In compounds of C60 with H2, NH4, and CO which is obtained via gas-phase intercalation, for example, the room-temperature symmetry is fcc, with variations of the lattice parameter of less than 0.2% compared to pristine fullerite. Only a minor lattice distortion is observed in N2-intercalated C60, which is obtained at high pressure (Galtsov et al, 2007), while O2 can diffuse even at atmospheric pressure through the interstices of C60 (Assink et al, 1992), which rationalizes its observed degradability by photooxidation (Hamed et al, 1993;Katz et al, 1998). These intermolecular interstices, especially the larger octahedral ones, are large enough to accommodate also the heavier alkali ions without distortion nor expansion of the fcc lattice, and cocrystallization of alkali fullerides with ammonia leads to only minor tuning of the lattice spacing.…”

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“…No liquid fullerene phases are known, and binary phases with other molecules cannot be obtained by mixing and cooling from the molten state at arbitrary proportions. Intercalation of gas-phase molecules into solid fullerite can be achieved by application of pressure (and sometimes high temperature) to the molecular gas to aid its diffusion through the interstices of C60 crystals; this method only works, however, for rare gases, methane, or small diatomic gases (Sundqvist, 2003;Galtsov et al, 2007). On the other hand, fullerenes are moderately soluble in a number of organic solvents (Ruoff et al, 1993) and stoichiometric solvates can be obtained by precipitation or slow evaporation.…”

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Physical Properties of Organic Fullerene Cocrystals

Macovez

2018

Front. Mater.

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The basic facts and fundamental properties of binary fullerene cocrystals are reviewed, focusing especially on solvates and salts of Buckminsterfullerene (C60), and hydrates of hydrophilic C60 derivatives. The examined properties include the lattice structure and the presence of orientational disorder and/or rotational dynamics (of both fullerenes and cocrystallizing moieties), thermodynamic properties such as decomposition enthalpies, and charge transport properties. Both thermodynamic properties and molecular orientational disorder shed light on the extent of intermolecular interactions in these binary solid-state systems. Comparison is carried out also with pristine fullerite and with the solid phases of functionalized C60. Interesting experimental findings on binary fullerene cocrystals include the simultaneous occurrence of rotations of both constituent molecular species, crystal morphologies reminiscent of quasicrystalline behavior, the observation of proton conduction in hydrate solids of hydrophilic fullerene derivatives, and the production of super-hard carbon materials by application of high pressures on solvated fullerene crystals.

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Intercalation of fullerite C60 with N2 molecules. An investigation by x-ray powder diffraction

Cited by 15 publications

References 32 publications

Effect of impurity oxygen molecules on the structural and thermodynamic properties of fullerite C60

Effect of impurity oxygen molecules on the structural and thermodynamic properties of fullerite C60

Synthesis and properties of C60 fullerite intercalated by acetylene

Physical Properties of Organic Fullerene Cocrystals

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