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Published byLeonard Melton Modified over 9 years ago
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Introduction to Quantum Theory of Angular Momentum
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Angular Momentum AM begins to permeate QM when you move from 1-d to 3-d This discussion is based on postulating rules for the components of AM Discussion is independent of whether spin, orbital angular momenta, or total momentum.
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Definition An angular momentum, J, is a linear operator with 3 components (Jx, Jy, Jz) whose commutation properties are defined as
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Or in component form
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Convention Jz is diagonal For example:
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Therefore Where |jm> is an eigenket h-bar m is an eigenvalue
For a electron with spin up Or spin down
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Definition These Simple Definitions have some major consequences!
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THM Proof: QED
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Raising and Lowering Operators
Raising Operator
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Product of J and J+
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Fallout
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Proof that J is the lowering operator
It is a lowering operator since it works on a state with an eigenvalue, m, and produces a new state with eigenvalue of m-1
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[J2,Jz]=0 indicates J2 and Jz are simultaneous observables
Since Jx and Jy are Hermitian, they must have real eigenvalues so l-m2 must be positive! l is both an upper and LOWER limit to m!
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Let msmall=lower bound on m and let mlarge=upper bound on m
mlarge cannot any larger
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Final Relation So the eigenvalue is mlarge*(mlarge +1) for any value of m
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Four Properties
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Conclusions As a result of property 2), m is called the projection of j on the z-axis m is called the magnetic quantum number because of the its importance in the study of atoms in a magnetic field Result 4) applies equally integer or half-integer values of spin, or orbital angular momentum
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END OF LECTURE 1
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Matrix Elements of J Indicates a diagonal matrix
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Theorems And we can make matrices of the eigenvalues, but these matrices are NOT diagonal
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Fun with the Raising and Lowering Operators
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A matrix approach to Eigenvalues
If j=0, then all elements are zero! B-O-R-I-N-G! Initial m j= 1/2 final m What does J+ look like?
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Using our relations, Answer: Pauli Spin Matrices
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J=1, An Exercise for the Students
Hint:
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Rotation Matices We want to show how to rotate eigenstates of angular momentum First, let’s look at translation For a plane wave:
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A translation by a distance, A, then looks like
translation operator Rotations about a given axis commute, so a finite rotation is a sequence of infinitesimal rotations Now we need to define an operator for rotation that rotates by amount, q, in direction of q
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So Where n-hat points along the axis of rotation
Suppose we rotated through an angle f about the z-axis
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Using a Taylor (actually Maclaurin) series expansion
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What if f = 2p? The naïve expectation is that thru 2p and no change.
This is true only if j= integer. This is called symmetric BUT for ½ integer, this is not true and is called anti-symmetric
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Let j=1/2 (for convenience it could be any value of j)
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Using the sine and cosine relation
And it should be no surprise, that a rotation of b around the y-axis is
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Consequences If one rotates around y-axis, all real numbers
Whenever possible, try to rotate around z-axis since operator is a scalar If not possible, try to arrange all non-diagonal efforts on the y-axis Matrix elements of a rotation about the y-axis are referred to by
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And Wigner’s Formula (without proof)
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Certain symmetry properties of d functions are useful in reducing labor and calculating rotation matrix
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Coupling of Angular Momenta
We wish to couple J1 and J2 From Physics 320 and 321, we know But since Jz is diagonal, m3=m1+m2
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Coupling cont’d The resulting eigenstate is called
And is assumed to be capable of expansion of series of terms each of with is the product of 2 angular momentum eigenstates conceived of riding in 2 different vector spaces Such products are called “direct products”
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Coupling cont’d The separateness of spaces is most apparent when 1 term is orbital angular momentum and the other is spin Because of the separateness of spaces, the direct product is commutative The product is sometimes written as
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Proof of commutative property
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The expansion is written as
Is called the Clebsch-Gordan coefficient Or Wigner coefficient Or vector coupling coefficient Some make the C-G coefficient look like an inner product, thus
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A simple formula for C-G coefficients
Proceeds over all integer values of k Begin sum with k=0 or (j1-j2-m3) (which ever is larger) Ends with k=(j3-j1-j2) or k=j3+m3 (which ever is smaller) Always use Stirling’s formula log (n!)= n*log(n) Best approach: use a table!!!
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What if I don’t have a table? And I’m afraid of the “simple” formula?
Well, there is another path… a 9-step path!
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9 Steps to Success Get your values of j1 and j2
Identify possible values of j3 Begin with the “stretched cases” where j1+j2=j3 and m1=j1, m2=j2 , and m3=j3, thus |j3 m3>=|j1 m1>|j2 m2> From J3=J1+J2,, it follows that the lowering operator can be written as J3=J1+J2
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9 Steps to Success, cont’d
Operate J3|j3 m3>=(J1+J2 )|j1 m1>|j2 m2> Use Continue to lower until j3=|j1-j2|, where m1=-j1 , m2= -j2, and m3= -j3 Construct |j3 m3 > = |j1+j2 -1 j1+j2-1> so that it is orthogonal to |j1+j2 j1+j2-1> Adopt convention of Condon and Shortley, if j1 > j2 and m1 > m2 then Cm1 m2j1 j2 j3 > 0 (or if m1 =j1 then coefficient positive!)
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9 Steps to Success, cont’d
Continue lowering and orthogonalizin’ until complete! Now isn’t that easier? And much simpler… You don’t believe me… I’m hurt. I know! How about an example?
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A CG Example: j1 =1/2 and j2 =1/2
Step 1 Step 2 Step 3
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Steps 4 and 5 and 6->
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Step 7—Keep lowering As low as we go
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An aside to simplify notation
Now we have derived 3 symmetric states Note these are also symmetric from the standpoint that we can permute space 1 and space 2 Which is 1? Which is 2? “I am not a number; I am a free man!”
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The infamous step 8 “Construct |j3 m3 > = |j1+j2 -1 j1+j2-1> so that it is orthogonal to |j1+j2 j1+j2-1>” j1+j2=1 and j1+j2-1=0 for this case so we want to construct a vector orthogonal to |1 0> The new vector will be |0 0>
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Performing Step 8 An orthogonal vector to this could be or
Must obey Condon and Shortley: if m1=j1,, then positive value j1=1/2 and |+> represents m= ½ , so only choice is
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Step 9– The End This state is anti-symmetric and is called the “singlet” state. If we permute space 1 and space 2, we get a wave function that is the negative of the original state. These three symmetric states are called the “triplet” states. They are symmetric to any permutation of the spaces
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A CG Table look up Problem
Part 1— Two particles of spin 1 are at rest in a configuration where the total spin is 1 and the m-component is 0. If you measure the z-component of the second particle, what values of might you get and what is the probability of each z-component?
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CG Helper Diagram m1 m2 j3 m3 C
It is understood that a “C” means square root of “C” (i.e. all radicals omitted)
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Solution to Part 1 Look at 1 x 1 table Find j3 = 1 and m3 = 0
There 3 values under these m1 m2 1 -1 1/2 -1/2
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So the final part m2 C Prob -1 1/2 1 -1/2
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Part 2 An electron is spin up in a state, y5 2 1 , where 5 is the principle quantum number, 2 is orbital angular momentum, and 1 is the z-component. If you could measure the angular momentum of the electron alone, what values of j could you get and their probabilities?
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Solution Look at the 2 x ½ table since electron is spin ½ and orbital angular momentum is 2 Now find the values for m1=1 and m2=1/2 There are two values across from these: 4/5 which has j3 = 5/2 -1/5 which has j3 = 3/2 So j3=5/2 has probability of 4/5 So j3 = 3/2 has probability of 1/5
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