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Rotational and Vibrational Spectra
Spectroscopy 1: Rotational and Vibrational Spectra CHAPTER 13
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Vibrations of Diatomic Molecules
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Fig 9.21 Energy levels of a harmonic oscillator
Solving Gives: where: Zero point energy
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Fig 13.26 Molecular potential energy curve:
approximates parabola only near bottom of well k ≡ force constant
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From the Schrodinger equation:
Fig The force constant is a measure of the curvature of the potential energy From the Schrodinger equation: stiff bond where: v = 0, 1, 2,... Vibrational terms: flexible bond
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Fig 13.28 The oscillation of a molecule may
result in an oscillating dipole Gross selection rule: The electric dipole of molecule must change when atoms are displaced Such vibrations are said to be: infrared active Specific selection rule: Δv = ±1 If the dipole does not change: infrared inactive
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Fig 13.29 Difference between well-depth De and
dissociation energy D0 Zero-point energy
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(accounts for anharmonicity)
Fig Morse potential energy curve (accounts for anharmonicity) Morse potential energy: where: Permitted energy levels: G(v) = (v+½) ṽ - (v+½)2χe ṽ where: anharmonicity constant
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Fig 13. 31 Dissociation energy is the sum of energy level
Fig Dissociation energy is the sum of energy level separations up to its dissociation limit
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Vibration-Rotation Spectra
Each line of a high-resolution vibrational spectrum consists of many closely-space lines Molecular spectra often called band spectra Structure is due to rotational transitions accompanying a specific vibrational transition A molecular rotation is enhanced or retarded by a vibrational transition When vibrational transition occurs, ΔJ changes by ±1 and sometimes 0 when ΔJ = 0 is allowed
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Fig 13.34 High resolution vibration-rotation
spectrum of HCl for a v + 1 ← v transition Combined vib-rot terms, S: S(v, J) = G(v) + F(J) = (v+½) ṽ + BJ(J+1)
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S(v+1, J+1) – S(v,J) = ṽ + 2B(J+1)
Fig Formation of P, Q, and R branches in vib-rot spectra When v+1 ← v occurs, ΔJ = ±1 (and sometimes 0) S(v+1, J-1) – S(v,J) = ṽ - 2BJ S(v+1, J) – S(v,J) = ṽ S(v+1, J+1) – S(v,J) = ṽ + 2B(J+1)
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