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The approximate temperature at which 20 % of hydrogen atoms are in the first excited state, when the fractional population of an excited state of energy E n compared to the population of the ground state of energy E 0 is given by N n / N 0 = e − ( E n − E 0 ) k B T .

The approximate temperature at which 20 % of hydrogen atoms are in the first excited state, when the fractional population of an excited state of energy E n compared to the population of the ground state of energy E 0 is given by N n / N 0 = e − ( E n − E 0 ) k B T .

Solution Summary: The author calculates the approximate temperature at which 20% of hydrogen atoms are in the first excited state, based on the expression for the Boltzmann equation.

College Physics

College Physics

2nd Edition

ISBN: 9780134601823

Author: ETKINA, Eugenia, Planinšič, G. (gorazd), Van Heuvelen, Alan

Publisher: Pearson,

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Question

Chapter 28, Problem 21P

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The approximate temperature at which 20% of hydrogen atoms are in the first excited state, when the fractional population of an excited state of energy En compared to the population of the ground state of energy E0 is given by Nn/N0=e−(En−E0)kBT.

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Chapter 28, Problem 20P

Chapter 28, Problem 22P

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Chapter 28 Solutions

College Physics

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