Heat capacity and vibrational spectra of monolayer films adsorbed in nanotubes

Ana Maria Vidales; Vincent H. Crespi; Milton W. Cole

doi:10.1103/PhysRevB.58.R13426

Heat capacity and vibrational spectra of monolayer films adsorbed in nanotubes

Ana Maria Vidales, Vincent H. Crespi, Milton W. Cole

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23 Scopus citations

Abstract

Carbon or boron nitride nanotubes can adsorb condensed-phase monolayer films on their inner surfaces. Examples include inert gas or hydrogen films, which form at low temperatures in nanotubes with radius (Formula presented) We study the phonon modes and thermodynamic properties of such films. Azimuthal quantization yields quasi-one-dimensional behavior at low temperature, manifested by a heat capacity linear in T, with quasi-two-dimensional behavior at higher temperature; the crossover between these regimes has a universal form, depending only on the ratio of the film radius to the thermal phonon wavelength. The film radius and mean sound speed can be extracted from the temperature dependence of the heat capacity.

Original language	English (US)
Pages (from-to)	R13426-R13429
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	58
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevB.58.R13426
State	Published - 1998

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.58.R13426

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abstract = "Carbon or boron nitride nanotubes can adsorb condensed-phase monolayer films on their inner surfaces. Examples include inert gas or hydrogen films, which form at low temperatures in nanotubes with radius (Formula presented) We study the phonon modes and thermodynamic properties of such films. Azimuthal quantization yields quasi-one-dimensional behavior at low temperature, manifested by a heat capacity linear in T, with quasi-two-dimensional behavior at higher temperature; the crossover between these regimes has a universal form, depending only on the ratio of the film radius to the thermal phonon wavelength. The film radius and mean sound speed can be extracted from the temperature dependence of the heat capacity.",

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year = "1998",

doi = "10.1103/PhysRevB.58.R13426",

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AU - Vidales, Ana Maria

AU - Crespi, Vincent H.

AU - Cole, Milton W.

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N2 - Carbon or boron nitride nanotubes can adsorb condensed-phase monolayer films on their inner surfaces. Examples include inert gas or hydrogen films, which form at low temperatures in nanotubes with radius (Formula presented) We study the phonon modes and thermodynamic properties of such films. Azimuthal quantization yields quasi-one-dimensional behavior at low temperature, manifested by a heat capacity linear in T, with quasi-two-dimensional behavior at higher temperature; the crossover between these regimes has a universal form, depending only on the ratio of the film radius to the thermal phonon wavelength. The film radius and mean sound speed can be extracted from the temperature dependence of the heat capacity.

AB - Carbon or boron nitride nanotubes can adsorb condensed-phase monolayer films on their inner surfaces. Examples include inert gas or hydrogen films, which form at low temperatures in nanotubes with radius (Formula presented) We study the phonon modes and thermodynamic properties of such films. Azimuthal quantization yields quasi-one-dimensional behavior at low temperature, manifested by a heat capacity linear in T, with quasi-two-dimensional behavior at higher temperature; the crossover between these regimes has a universal form, depending only on the ratio of the film radius to the thermal phonon wavelength. The film radius and mean sound speed can be extracted from the temperature dependence of the heat capacity.

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Heat capacity and vibrational spectra of monolayer films adsorbed in nanotubes

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