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Revision 3 as of 3:55PM, Jan 13, 2012
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Editor: HSLee
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Revision 12 as of 11:12AM, Jan 28, 2012
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Editor: Sam
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Deletions are marked like this. Additions are marked like this.
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 * <<la("PH102_HW1_rev.pdf","Homework 1, Due: Jan 20")>>"  * ~+'''Homework 1'''+~, ~-due Jan 20-~: <<la("hw1rev.pdf", "Potential step, well")>>
 {{{#!wiki comment
   * Revised (marked by the red text in the file)
     * <<color(Correction)>>: Problem 4(a), $B > 0$ when $U_0 > 0$ and $B < 0$ when $U_0 < 0$.
     * <<color(Correction)>>: Problem 4(b), "the similarity" &rarr; "the similarity or the difference".
  }}}
 * ~+'''Homework 1 Solutions'''+~, ~-due Jan 20-~: <<la("HW1SOL.pdf", "Potential step, well")>>
 * ~+'''Homework 2'''+~, ~-due Jan 30-~: <<la("HW2rev.pdf", "Schrodinger Equation: Hydrogen Atom")>>
* Revised (marked by the red text in the file)
     * <<color(Addition, green)>>: Problem 3: Hamiltonian and invariance relationships are discussed to help you solve the problem.
     * <<color(Correction)>>: Problem 4: $\Phi (\pm 1) = \frac{1}{\sqrt{2\pi}} e^{\pm i \phi}; $\Phi (\pm 2) = \frac{1}{\sqrt{2\pi}} e^{\pm 2 i \phi}$
     * <<color(Addition, green)>>: Problem 5: The way to test orthogonality between the two wave functions is added.
  }}}

* Revised (marked by the red text in the file)

  • Addition: Problem 3: Hamiltonian and invariance relationships are discussed to help you solve the problem.

  • Correction: Problem 4: $\Phi (\pm 1) = \frac{1}{\sqrt{2\pi}} e^{\pm i \phi}; $\Phi (\pm 2) = \frac{1}{\sqrt{2\pi}} e^{\pm 2 i \phi}$

  • Addition: Problem 5: The way to test orthogonality between the two wave functions is added.

  • }}}
UC Santa Cruz Department of Physics