Statistical Physics, Part 1A lucid presentation of statistical physics and thermodynamics which develops from the general principles to give a large number of applications of the theory. |
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Page 76
... rotation . For the same reason , the total energy E of a rotating body may be written as the sum of its internal energy ( here denoted by E ) and its kinetic energy of rotation : E = Ein + M2 / 21 , ( 26.10 ) where I is the moment of ...
... rotation . For the same reason , the total energy E of a rotating body may be written as the sum of its internal energy ( here denoted by E ) and its kinetic energy of rotation : E = Ein + M2 / 21 , ( 26.10 ) where I is the moment of ...
Page 139
... rotation and the vibrations of atoms within the molecule . Let us next calculate the rotational free energy . If the temperature is so high that Th2 / 21 ( i.e. the " rotational quantum " 2/21 is small compared with T ) , then the terms ...
... rotation and the vibrations of atoms within the molecule . Let us next calculate the rotational free energy . If the temperature is so high that Th2 / 21 ( i.e. the " rotational quantum " 2/21 is small compared with T ) , then the terms ...
Page 149
... rotation is therefore Erot = M2 M2 M + + 21 , 212 213 " ( 51.2 ) where § , n , are coordinates in a rotating system ... rotation through 360 ° ( the identical transformation ) . Denoting this number * by σ , we can take the integration ...
... rotation is therefore Erot = M2 M2 M + + 21 , 212 213 " ( 51.2 ) where § , n , are coordinates in a rotating system ... rotation through 360 ° ( the identical transformation ) . Denoting this number * by σ , we can take the integration ...
Contents
Elementary excitations in a quantum Fermi liquid | 1 |
Interaction of quasiparticles | 2 |
Magnetic susceptibility of a Fermi liquid | 3 |
Copyright | |
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atoms axis body Bravais lattice calculate cell chemical potential classical coefficients components concentration condition constant coordinates correlation function corresponding critical point crystal denote density depends derivative determined electron elements entropy equal equation expansion expression Fermi field fluctuations formula free energy frequency gases Gibbs distribution given gives Hamiltonian Hence ideal gas integral interaction irreducible representations liquid macroscopic magnetic matrix mean square mean value molecule momenta momentum motion N₁ number of particles obtain order parameter P₁ partition function phase transition phonon plane pressure PROBLEM properties Quantum Mechanics reciprocal lattice regarded relation result rotational second kind solid solution solvent space group specific heat statistical substance Substituting subsystem suffix surface symmetry temperature theory thermal thermodynamic potential thermodynamic quantities tion total number transformation transition point vapour variables velocity vibrations volume zero ӘР