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A university homework assignment focused on understanding and implementing finite rotations on creation and annihilation operators in the context of angular momentum using schwinger's approach. The assignment includes three problems: deriving a relationship between angular momentum operators in different directions, deriving a specific equation using commutation relations, and expressing eigenstates of angular momentum in a given direction as a sum of eigenstates in the z-direction.
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momentum. Specifically, it concerns implementing finite rotations on the creation and annihilation
operators.
a. Using the definitions of the operators J
ˆ
r in terms of the creation and annihilation
2
( ˆ ,ˆ ),ˆ (ˆ ,ˆ )
k k a a J a a
σ
−
−
= − where
k
−
a a is a row vector..
b. From the result in a. show that
⎠
⎞ ⎜ ⎝
⎛ ⎟ − ⋅ ⎠
⎞ ⎜ ⎝
⎛ ⋅
−
−
cos / 21 sin( / 2 (ˆ ,ˆ )ˆ
ˆ (ˆ ,ˆ )exp ˆ
ˆ exp ˆ
r r
where 1 is the identity matrix. Hint: consider infinitesimal results and integrate
( )!( )!
j m j m
a a jm
jm jm
− −
derive eq. 3.5.41 starting from Eqs. 3.8.13 and using
only the commutation relations for the creation and annihilation operators for the harmonic oscillator.
principle, one could take any direction. The purpose of this problem is to relate an eigenstate of n J
r
⋅ (where n ˆ
is an arbitrary unit vector) in terms of eigenstates in the z-direction. In principle this can be implemented
straightforwardly using the Wigner –D matrices. In this problem, however, I want you to use Schwinger’s
approach directly.
a. As a first example, I want you to consider a state with fixed j ( i.e. an eigenstates of
J and
of n J
r
⋅ with eigenvalue of j ( i.e. the maximum possible value) and express it as sum of states
r
m m^
coefficients m c.
b. As a second example, I want you to consider a state with fixed j ( i.e. an eigenstates of
and of n J
r
⋅ with eigenvalue of j- 1 ( i.e. one les than the the maximum possible value) and express
it as sum of states with good j , m. That is, if we define Φ such that Φ = ( + 1 )Φ
2 J j j and
n ˆ^ J j
r
and express Φ as
m m^
d jm , I want you to use Schwinger’s
approach to find the coefficients m d.
Sakurai Chapter 3: 13, 15, 16