Proceedings of the International School of Physics "Enrico Fermi.", Volume 27N. Zanichelli, 1953 - Nuclear physics |
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Page 144
... energy iso- meric relaxation will occur . T1 translational energy -ん。 internal vibrational degrees of freedom rotational isomeric energy Fig . 7. Box diagram showing possible routes by which energy can be transferred into isomeric ...
... energy iso- meric relaxation will occur . T1 translational energy -ん。 internal vibrational degrees of freedom rotational isomeric energy Fig . 7. Box diagram showing possible routes by which energy can be transferred into isomeric ...
Page 280
... energy E , has at every moment the value it would have if the external perturbation were frozen at its momentary value . If the perturbation finally disappears again ( here , because A has moved away ) , the energy returns to its ...
... energy E , has at every moment the value it would have if the external perturbation were frozen at its momentary value . If the perturbation finally disappears again ( here , because A has moved away ) , the energy returns to its ...
Page 426
... energy from them . This amounts to say that the phonons of the elastic waves collide with the imper- fections and the collisions on the average are not perfectly elastic . After more or less complex processes the energy subtracted is ...
... energy from them . This amounts to say that the phonons of the elastic waves collide with the imper- fections and the collisions on the average are not perfectly elastic . After more or less complex processes the energy subtracted is ...
Contents
GREENSPAN Translational dispersion in gases | 73 |
J LAMB | 101 |
T A LITOVITZ Ultrasonic relaxation in liquids | 176 |
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absorption Acoust activation energy amplitude atoms attenuation Boltzmann equation calculated chain Chem CO₂ coefficient collision complex compressibility concentration constant courbe curve d'absorption density dipole dispersion dissociation distribution dyn/cm² elastic electrolytes electrons energy entropy of fusion equation equilibrium equilibrium constant experimental factor function gases given heat conduction imperfections interaction ionic atmosphere ions isotherme Journ kinetic l'équilibre lattice liquid LITOVITZ maximum Maxwell distribution mean free path measurements method modulus molecular motion obtained parameters paramètres peak peut Phys polyisobutylene polymer pressure quartz crystal range ratio reaction relaxation effects relaxation frequency relaxation processes Rendiconti S.I.F. rotation segment shear shown in Fig solution solvent sound specific heat stiffness structural temperature temps de relaxation theory thermal tion transition trempe ultrasonic valeur variation velocity vibrational viscosity volume water molecules wave