| 21. | From Maxwell Boltzmann distribution it seems the average speed is proportional to the square root of the temperature.
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| 22. | Here, the Maxwell� Boltzmann distribution of energies must be considered, which leads to the modified expression,
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| 23. | We can model the electrons at the sheath edge with a Maxwell� Boltzmann distribution, i . e .,
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| 24. | The Maxwell� Boltzmann distribution also requires low density, implying that g _ i \ gg N _ i.
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| 25. | These fluctuations happen on time scales which are much larger than the microscopic relaxation times to the Boltzmann distribution.
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| 26. | Fluorescence is most effective when there is a larger ratio of atoms at lower energy levels in a Boltzmann distribution.
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| 27. | Since at temperature " T " the molecules have energies given by a Boltzmann distribution, frequency factor.
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| 28. | The " configuration probability " is given by the Boltzmann distribution with inverse temperature ? e " 0:
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| 29. | The fraction of molecules occupying a given vibrational mode at a given temperature can be calculated using the Boltzmann distribution.
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| 30. | :: : Depending on your mathematical background, the OP may want to consider looking into Maxwell� Boltzmann distribution.
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