130_notes.dvi

n= 0, 1 , 2 , 3 ...

Theangular momentum must be quantized in units of ̄h.

This will prove to be true for 3 dimensions too, however, the 3 components of angular momentum
do not commute with each other, leading to all kinds of fun.

9.7 Derivations and Computations

9.7.1 Probability Flux for the Potential Step*

The probability flux is given by

j(x,t) =

̄h

2 mi

[

ψ∗

∂ψ

∂x

−

∂ψ∗

∂x

ψ

]

We can save some effort by noticing that this contains an expressionminus its complex conjugate.
(This assures that term in brackets is imaginary and the flux is then real.)

j=

̄h

2 im

[

u∗

du

dx

−

du∗

dx

u

]

=

̄h

2 im

[

u∗

du

dx

−CC

]

Forx < 0

j =

̄h

2 im

[(e−ikx+R∗eikx)(ikeikx−ikRe−ikx)−CC]

j =

i ̄hk

2 im

[1−Re−^2 ikx+R∗e^2 ikx−R∗R] +CC

j = [1−|R|^2 ]

̄hk

m

The probability to be reflected is the reflected flux divided by the incident flux. In this case its easy
to see that its|R|^2 as we said. Forx > 0

j=|T|^2

̄hk′

m

The probability to be transmitted is the transmitted flux divided by the incident flux.

|T|^2

̄hk′

m

m

̄hk

=

4 k^2

(k+k′)^2

k′

k

=

4 kk′

(k+k′)^2

again as we had calculated earlier.

9.7.2 Scattering from a 1D Potential Well*

V(x) =







0 x <−a

−V 0 −a < x < a

0 x > a