The Morse oscillator modeling a different diatomic molecule has D = 324 kJ/mole and v = 1240 cm¹. (Again, 11.9627 J/mole = 1 cm-¹.) wwww (a) What is the energy of the pictured eigenfunction? Report the energy in cm-¹ using the formula for the Morse oscillator energy levels. (b) How close to the dissociation limit is this state in kJ/mole, that is, what is the energy difference between this state and molecular dissociation?
The Morse oscillator modeling a different diatomic molecule has D = 324 kJ/mole and v = 1240 cm¹. (Again, 11.9627 J/mole = 1 cm-¹.) wwww (a) What is the energy of the pictured eigenfunction? Report the energy in cm-¹ using the formula for the Morse oscillator energy levels. (b) How close to the dissociation limit is this state in kJ/mole, that is, what is the energy difference between this state and molecular dissociation?
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Transcribed Image Text:The Morse oscillator modeling a different diatomic molecule has D = 324 kJ/mole and v =
1240 cm¹. (Again, 11.9627 J/mole = 1 cm-¹.)
M
(a) What is the energy of the pictured eigenfunction? Report the energy in cm-¹ using the
formula for the Morse oscillator energy levels.
(b) How close to the dissociation limit is this state in kJ/mole, that is, what is the energy
difference between this state and molecular dissociation?
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