Explanation It is given that the kinetic energy is 5 % of the required activation energy and the activation energy is equal to the electrostatic potential energy of the system of nuclei. Write the expression for the relationship between the kinetic energy and the electrostatic potential energy of the system of nuclei. K av = 0.05 U (I) Here, K av is the average kinetic energy and U is the electrostatic potential energy of the system of nuclei. Write the equation for K av . K av = 3 2 k B T (II) Here, k B is the Boltzmann constant and T is the temperature. Write the equation for the electrostatic potential energy. U = k q 1 q 2 r Here, U is the electrostatic energy due to the point charges q 1 , q 2 , k is the coulomb constant and r is the distance between the charges. The charges of the two nuclei are + e . Replace q 1 and q 2 by + e in the above equation. U = k ( + e ) ( + e ) r = k e 2 r (III) Put equations (II) and (III) in equation (I). 3 2 k B T = 0.05 k e 2 r T = 0.1 k e 2 3 k B r (IV) Conclusion: The value of k is 8

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Chapter 17, Problem 124P

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The temperature at which the average kinetic energy of the deuterium atom is 5% of the required activation energy for the reaction.

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Chapter 17, Problem 123P

Chapter 17, Problem 125P

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The temperature at which the average kinetic energy of the deuterium atom is 5 % of the required activation energy for the reaction.

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The temperature at which the average kinetic energy of the deuterium atom is 5% of the required activation energy for the reaction.

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Chapter 17 Solutions