2: Diatomics

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2.1: Overview
This page delves into the complexities of molecular motion and its impact on chemical reactions influenced by thermal energy. It highlights the importance of analyzing various types of motions—translational, rotational, vibrational, and electronic—separately. The role of the partition function in calculating thermodynamic quantities is emphasized, along with the concept of separability for total molecular partition functions.
2.2: Translation
This page explores the translational energy levels of a particle in a three-dimensional cubic box through the Schrödinger equation. It introduces the translational partition function as a product of sums over quantum states, which can be approximated as integrals due to closely spaced energy levels relative to thermal energy. The page concludes with an analytical evaluation of the partition function.
2.3: Rotation
This page covers the rigid rotor approximation in quantum mechanics, focusing on solutions to the rotational Schrödinger equation, with energy levels indexed by rotational quantum number and inversely proportional to moment of inertia. It highlights rotational energy level degeneracies and defines the rotational partition function for diatomic molecules, including a high-temperature approximation.
2.4: Vibration
This page gives a formula for vibrational energy levels of diatomic molecules using the quantum harmonic oscillator model as the foundation for defining and computing the vibrational partition function. It is shown that this expression may be evaluated numerically or analytically.
2.5: Electronic
This page demonstrates that the spacing between electronic energy levels almost always precludes thermal excitation.
2.6: Internal Energies
This page covers the computation of thermal energies using Boltzmann factors and the partition function, focusing on optimal differentiation techniques for analytically expressible partition functions. It gives formulas for thermal energies as a function of temperature for translational, rotational, and vibrational modes of motion and presents a worked example for a collection of non-interacting CO molecules.
2.7: Entropies
This page explores the computation of mode-specific entropies for distinguishable non-interacting diatomic molecules using partition functions and thermal energies. It includes formulas for rotational and vibrational entropies, particularly at extreme temperatures, and addresses the need for corrections in translational entropy due to indistinguishability, recommending the Sackur-Tetrode equation under specific pressures.
2.8: Summary
This page describes how the thermal population of energy levels in molecules is related to the underlying energy level spacings, indicating that translational states are populated more easily than rotational, which are more accessible than vibrational states. Excited electronic states are usually not thermally accessed.

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