The course book, Gasiorowicz (G2), spends chapter 7 on operator methods for the SHO, followed by chapter 10 on the central force problem and rotational invariance, and then chapter 11 on Angular Momentum per se. We are cross-cutting through this argument very quickly, and will then return to cut through these and intervening chapters from another angle, mostly after Spring break.

I am putting up some initial thoughts which may become pages for clarification, or which might lead to projects. Please suggest additions which may be of use to current and future students. Those of you who need page numbers in Liboff, please see me in person. All references are to Gasiorowicz 2nd Edition (1996) and Liboff 3rd Edition (1998). The corresponding chapter references for Gasiorowicz 3rd edition (2003) are given here.

Operator Methods (G2 p130-144) 

• Chapter 7 starts with operator methods for the SHO, and then goes on to time dependence of operations and questions of representations. Master the SHO stuff early on, in time for the mid-term exam and the early part of Problem set#3. We will come back to some of the other stuff later on.

• Chapter 11 starts with the eigenvalue equations for both L_z and L² in terms of the spherical harmonics Y_lm which are a function of the two angular variables, theta and phi. You should have handouts showing the angular character for the few lowest l and m values, and be fully familiar with the conditions |m| ≤ l, etc, for l = 0,1,2,.. An arbitrary angular wavefunction can be expanded in terms of these eigenfunctions (see G2 p 198-9).
• To find the eigenfunction and show that the eigenvalue of L_z = m(h/2p) is straightforward. To show that the eigenvalue of L² is l(l+1)(h/2p)² requires the raising and lowering operators (L₊ and L_ ), and some algebra (see G2 p 190-4), which we could usefully make into a web page. Note how similar much of this material is to the corresponding treatment of the SHO.

• We will not do the later parts of chapter 11 involving complicated maths!