Simple Harmonic Oscillator. For a CO (carbon monoxide) molecule, assume that the system vibrates at o=4.0.1014 [Hz]. a. Wavefunction: Sketch the wave function for the n=5 state of the SHO. Points will be given on qualitative accuracy of the solution. Include a brief description to help me understand critical components of your sketch and label the sketch appropriately. b. Probabilities: Make a qualitatively correct sketch that indicates the probability of finding the state as a function of interatomic separation for n=5 indicate any important features. (Sketch plus 1 sentence). c. Classical turning points: Calculate the probability that the interatomic distance is outside the classically allowed region for the n=1 state

a. For the n=5 state of the SHO, the wavefunction is a symmetric Gaussian curve centered at the equilibrium position, with decreasing amplitudes as you move away from it.

b. The probability of finding the n=5 state as a function of interatomic separation is depicted as a plot showing a peak at the equilibrium position and decreasing probabilities as you move away from it.

c. The probability of the interatomic distance being outside the classically allowed region for the n=1 state of the SHO is negligible, as the classical turning points are close to the equilibrium position and the probability significantly drops away from it.

a. Wavefunction: The wave function for the n=5 state of the Simple Harmonic Oscillator (SHO) can be represented by a Gaussian-shaped curve centered at the equilibrium position. The amplitude of the curve decreases as you move away from the equilibrium position. The sketch should show a symmetric curve with a maximum at the equilibrium position and decreasing amplitudes as you move towards the extremes.

b. Probabilities: The probability of finding the state as a function of interatomic separation for the n=5 state of the SHO can be depicted as a plot with the probability density on the y-axis and the interatomic separation on the x-axis. The sketch should show a peak at the equilibrium position and decreasing probabilities as you move away from the equilibrium. The important feature to highlight is that the probability distribution extends beyond the equilibrium position, indicating the possibility of finding the molecule at larger interatomic separations.

c. Classical turning points: In the classical description of the Simple Harmonic Oscillator, the turning points occur when the total energy of the system equals the potential energy. For the n=1 state, the probability of the interatomic distance being outside the classically allowed region is negligible. The classical turning points are close to the equilibrium position, and the probability of finding the molecule significantly drops as you move away from the equilibrium.

Learn more about Probability from the link given below.

https://brainly.com/question/31828911

#SPJ4