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Page 197
... ( v ) , = ( 9 + ) , · of which a proof is given in ( 18.16 ) , show that We integrate this to obtain T др ( ~~ ) , = 7 ( 27 ) ... versus V at T = 200 K. Neglect the third virial coefficient . U ( T , V ) – U ( T 12 Ideal Gas Calculations 197.
... ( v ) , = ( 9 + ) , · of which a proof is given in ( 18.16 ) , show that We integrate this to obtain T др ( ~~ ) , = 7 ( 27 ) ... versus V at T = 200 K. Neglect the third virial coefficient . U ( T , V ) – U ( T 12 Ideal Gas Calculations 197.
Page 330
... versus 1 / T . The vertical scale is loga- rithmic . The dashed line is a straight line . 10-2 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 103 / T , in deg evaporation of one molecule . If Lo refers instead to one mole , then ( 20 ) becomes p ( T ) ...
... versus 1 / T . The vertical scale is loga- rithmic . The dashed line is a straight line . 10-2 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 103 / T , in deg evaporation of one molecule . If Lo refers instead to one mole , then ( 20 ) becomes p ( T ) ...
Page 336
... versus pressure for van der Waals equation of state : T = 0.90Tc . ( Courtesy of R. Cahn . ) Gas -Vapor pressure ... versus pressure for van der Waals equation of state : T = 0.95Tc . 0.7 0.9 р Pc 0.8 - > ( -0.2 T = TC -0.3 Liquid G NTC ...
... versus pressure for van der Waals equation of state : T = 0.90Tc . ( Courtesy of R. Cahn . ) Gas -Vapor pressure ... versus pressure for van der Waals equation of state : T = 0.95Tc . 0.7 0.9 р Pc 0.8 - > ( -0.2 T = TC -0.3 Liquid G NTC ...
Contents
STATES OF THE MODEL SYSTEM | 11 |
AN ELEMENTARY SOLUBLE SYSTEM | 17 |
SHARP PEAK OF gN | 19 |
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approximation Boltzmann bosons calculated Carnot cycle chemical potential classical regime closed system cm³ combined system concentration defined definition denote derivative diffusive contact dipole distribution function electric field electron energy levels ensemble entropy equal equation equilibrium ergs example expansion experimental Fermi energy Fermi gas Fermi-Dirac fermions Figure fluctuations flux fractional free energy free particle frequency gases given grand sum He¹ He³ heat capacity helium ideal gas law increase integral isothermal kinetic lattice liquid low temperature m₁ magnetic field magnetic moment model system molecule N₁ negative temperature number of accessible number of atoms number of particles occupied P₁ partition function photons plotted pressure probable configuration Problem properties quantity quantum number reservoir result spin excess superfluid system in thermal term thermal average thermal contact thermodynamic potential total number U₁ unit velocity versus volume white dwarf ат