Physics
Q1: The shape of wave functions
Match the following cross sections of the xzxz plane of various states of the hydrogen atom with the descriptions below. Some are pure atomic states, some are hybrid states, and some are molecular states. To distinguish them, see if there is one nucleus or two, and how many radial and planar nodes you can detect. One image and one description do not match; provide a sketch of the wave function that is not pictured and a description of the one shown in the surplus picture.
- a pure 3s3s state
- a pure 3d3d state
- a hybrid 3sd3sd state
- an antibonding 2σsp2σsp state
- a bonding 2πpp2πpp state
- a bonding 3σss3σss molecular state
Q2: Pick and mix - approximate solutions of complicated quantum systems
- Which “ingredient” fundamental systems are best used for this purpose? In which order are they invoked?
- Choose a suitable reference frame and sketch the geometry of the system and its position in the reference frame. Let d be the bond length.
- Plot the potential against each of the three coordinates of your chosen reference frame (keeping the other coordinates constant).
- Explain how the treatment of the system would change if the temperature was higher.
Q3: Perturbation - the anharmonic oscillator
Mathematical techniques to derive Schrodinger solutions (i.e. eigenfunction/eigenvalue pairs) for new sys- ¨ tems from solutions for known systems include the variation and perturbation techniques.
- Explain the difference between the harmonic and the anharmonic oscillator models. Illustrate the need for the anharmonic correction by reference to the vibration states of a linear two-atom molecule.
Q4: Atomic Model
Describe the atomic model. What’s the problem of Niels Bohr’s atomic model?
Q5: Quantitative Reasoning
A football’s weight is 0.4 kg and the speed is 30 m/s. Calculate the wavelength of the football
Calculate the de Broglie wavelength of an electron traveling at 2% the speed of light.
Calculate the de Broglie wavelength of an ball traveling at 330 m/s.