A New Free Volume Theory Based on Microscopic Concept of Molecular Collisions for Penetrant Self-Diffusivity in Polymers
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概要
- 論文の詳細を見る
A new free volume theory, which we named “shell-like free volume” theory, is developed for penetrant diffusivity in polymers by introducing microscopic concept of molecular collisions. Shell-like free volume is defined as the ambient free space of the penetrant molecule; it is consistent with the notion of molecular collisions, which is the microscopic origin of molecular diffusion. The microscopic notion can give physical meaning to all the parameters in the theory, and the parameters can be evaluated using the only pure-component parameters: the experimental viscosity of the solvent, the viscoelasticity of the polymer, and the molecular surface area estimated from the chemical structure using the semiempirical quantum chemical calculation. The predictive ability of the shell-like free volume theory is good for self-diffusivities of molecules with shapes from spherical to chain-like in polymer solutions over wide ranges of temperature and concentration.
- 社団法人 化学工学会の論文
- 2009-03-01
著者
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Yamaguchi Takeo
Tokyo Inst. Technol. Kanagawa Jpn
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Ito Taichi
Chemical Resources Laboratory Tokyo Institute Of Technology
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Ito Taichi
Department Of Chemical System Engineering The University Of Tokyo
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Ohashi Hidenori
Chemical Resources Laboratory, Tokyo Institute of Technology
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Yamaguchi Takeo
Chemical Resources Laboratory, Tokyo Institute of Technology
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Yamaguchi Takeo
Chemical Resources Laboratory Tokyo Institute Of Technology
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Ohashi Hidenori
Chemical Resources Laboratory Tokyo Institute Of Technology
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Ito Taichi
Center For Disease Biology And Integrative Medicine Department Of Bioengineering Faculty Of Medicine
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Yanagimoto Tatsunori
Department Of Chemical System Engineering The University Of Tokyo
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