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Heat capacity of the lattice

Heat capacity of the lattice. General Theories. Thermodynamics. for. no numerical value at finite T. Classical Statistical Mechanics. Dulong-Petit law, numerical value independent of T. For details see Mandl. Classical Statistical Mechanics. Heat capacity: classical thermodynamics.

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Heat capacity of the lattice

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  1. Heat capacity of the lattice

  2. General Theories Thermodynamics for no numerical value at finite T Classical Statistical Mechanics Dulong-Petit law, numerical value independent of T For details see Mandl Classical Statistical Mechanics

  3. Heat capacity: classical thermodynamics • In the limit of ever lower temperatures for T1, CV must vanish to comply with the third law of thermodynamics. We also get information about the heat capacity at T=0. for a reversible process and at constant volume

  4. Heat capacity: classical thermodynamics • So classical thermodynamics does not tell us anything about the heat capacity of solids at finite temperature but we know that it must vanish at zero temperature.

  5. Heat capacity: classical statistical mechanics • The equipartition theorem states that every generalized position or momentum co-ordinate which occurs only squared in the Hamiltonian contributes a mean energy of (1/2) kBT to the system. • This theorem is based on the classical partition function, an integral in phase space. It is not valid if the real quantum mechanical energy levels are separated by an energy interval large compared to kBT. • The equipartition theorem allows us to make a quantitative prediction of the heat capacity, even though this prediction contradicts the vanishing heat capacity ot 0 K which was obtained from a more general principle. At sufficiently high temperatures, the prediction should still be ok.

  6. Heat capacity: classical statistical mechanics so for a one classical dimensional harmonic oscillator we have so the mean energy is kBT. For a three-dimensional oscillator we have 3 kBT. For one mole of ions we get and so This is called the Dulong-Petit law.

  7. Comparison of the Dulong-Petit law to experiment • At high temperatures the Dulong-Petit law works quite well. • At low temperatures, it does not. But we already know from basic principles that it wouldn’t. values of one mole of substance 7

  8. Heat capacity of diamond

  9. The Einstein model for the heat capacity • correct Dulong-Petit value for high temperatures • zero heat capacity at zero temperature • The Einstein frequency / temperature is an adjustable parameter.

  10. The Einstein model: low-temperature heat capacity • but low temperature behaviour of the experiment not correctly reproduced. T3 behaviour in experiment, exponential behaviour here for very low T 10

  11. Why does the Einstein model work at high T?Why does it fail at low T? • At high T the small spacing between the energy levels is irrelevant. • At sufficiently low temperature, the energy level separation is much bigger than kBT. • Eventually all the oscillators are “frozen” in the ground state. Increasing T a little does not change this, i.e. it does not change the energy.

  12. total number of states for a maximum |k|

  13. The Debye model for the heat capacity substitute low temperature, large for one mole

  14. Comparison Debye model - experiment

  15. Why does the Debye model work better at low T than the Einstein model? • The Debye model gives a better representation for the very low energy vibrations. • At low temperatures, these vibrations matter most.

  16. Limits of the Debye model

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