Introduction to Time dependent Time-independent methods: Kap. 7-lect2 ) , ( ˆ ) , ( t r H t r t i ) , ( ) , ( ˆ t r E t r H Methods to obtain an approximate eigen energy, E and wave function: perturbation methods Perturbation theory Variational method Scattering theory ) , ( ) ( ) , ( t r t c t r n n n Ground/Bound states Continuum states on degenerate states Methods to obtain an approximate expression for the expansion amplitudes. Approximation methods in Quantum Mechanics Degenerate states Golden Rule
Transcript
Introduction to
Time dependentTime-independent methods:
Kap. 7-lect2
),(ˆ),( trHtrt
i
),(),(ˆ trEtrH
Methods to obtain an approximate eigen energy, E and wave function:
perturbation methods
Perturbation theory Variational method Scattering theory
),()(),( trtctr nn
n
Ground/Bound states Continuum states
Non degenerate states
Methods to obtain an approximate expression for the expansion amplitudes.
Approximation methods in Quantum Mechanics
Degenerate states
GoldenRule
Scattering Theory:
• Classical Scattering:– Differential and total cross section– Examples: Hard sphere and Coulomb
scattering
• Quantal Scattering:– Formulated as a stationary problem– Integral Equation– Born Approximation– Examples: Hard sphere and Coulomb scattering
ddd
dd
d
d)sin(
0
2
0
scin
dNj
dtd
Number of scattered particles into :
insc jdj
per unit time:
dj
j
d
d
in
scDifferential Cross Section:
Total Cross Section:
Dimension: AreaInterpretation: Effective area for scattering.
Dimension: NoneInterpretation: ”Probability” for scattering into d
innj
ddscj
The Scattering Cross Section (To be corrected, see Endre Slide)
ddd
dd
d
d)sin(
0
2
0
Number of scattered particles into :
Differential Cross Section:
Total Cross Section:
innj
dd
The Scattering Cross Section
Nout
Nout
Quantal Scattering - No Trajectory! (A plane wave hits some object and a spherical wave emerges)
innj
dd
r
eCf
ikr
scattered ),(
scatteredinn
rkiinn Ce
• Solve the time independent Schrödinger equation• Approximate the solution to one which is valid far away from the scattering center• Write the solution as a sum of an incoming plane wave and an outgoing spherical wave.• Must find a relation between the wavefunction and the current densities that defines the
cross section.
Procedure:
scj
Current Density:
imm
ij *** Re)(
2
Incomming current density:
2C
m
kjin
Outgoing spherical current density:
2
22),(
mr
kfCjsc
r
eCf
ikr
sc ),(
ikzrkiin CeCe
zyx ez
fe
y
fe
x
frf
)(
eeer
fr
.......
2),(),(
rOr
eikCf
r
eCf
r
ikrikr
Example - Classical scattering:
d
b
bdbdd
ddd
dd )sin(
d
dbb
d
d
sin
b R
2
2cos
R
b
2sin
2
R
d
db
4
2R
d
d
2R
Hard Sphere scattering:
Independent of angles!= Geometrical Cross sectional area of sphere!
Example from 1D:
scatteredinn
0V
0
22
2V
m
kE
ikxikxscattered BeAeC
ikxBe
B
Af ),(
Forward scattering
Reflection
ikxinn Ce
ikxAe
In this case (since potential is discontinuous) we can find f excactly by ”gluing”
The Schrödinger equation - scattering form:
)( )( )(2
22
rErrVm
)( )()( 22 rrUrk
:get we)(2
)( and 2
with 2
22
rVm
rUm
kE
Now we must define the current densities from the wave function…
The final expression:
2
2
22
2
22
),(),(
f
mk
Cd
drfmrk
C
jd
drj
d
d
in
sc
2),(
fd
d
Summary
Then we have:
2),(
fd
d
…. Now we can start to work
)( )()( 22 rrUrk
Write the Schrödinger equation as:
)),(( r
efeC
ikrrki
Asymptotics:
Integral equation
)( )()( 22 rrUrk
)()(G ''22 rrrrk
With the rewritten Schrödinger equation we can introducea Greens function, which (almost) solves the problem for a delta-function potential:
Then a solution of:
can be written:
rdrrUrrGrr 30 )()()()()(
where we require: 0)( 022 rk
because….
rdrrUrrGkrkrk 3220
2222 )()()()()()()()(
This term is 0 This equals )( rr
Integration over the delta function gives result:
)()()()( 22 rrUrk
rdrrUrrGrr 30 )()()()()(
Formal solution:
Useless so far!
Must find G(r) in )()(G ''22 rrrrk
Note: sder rsi 33)2(
1)(
rsirsi ese 22and:
sdekssdek rsirsi 322322 )()(
sdks
erG
rsi3
222)2(
1)(
)()2(
1)()( 3
322 rrderGk rsi
r
erG
rki
4)(
Then:
The function: solves the problem!
”Proof”:
The integral can be evaluated, and the result is:
rdrrUrr
eer
rrikrki
3
01 )()(4
1)(
Inserting G(r), we obtain:
0)( 022 rk
implies that:
rkier )(0
rdrrUrr
eer
rrikrki
3)()(
4
1)(
At large r this can be recast to an outgoing spherical wave…..
The Born series:
rkier )(0
rdrrUrr
eer
rrikrki
3
12 )()(4
1)(
And so on…. Not necesarily convergent!
rdrrUrr
eer
rrikrki
3
01 )()(4
1)(
We obtains:
rdrrUrr
eer
rrikrki
3)()(
4
1)(
At large r this can be recast to an outgoing spherical wave…..
The Born series:
rkier )(0
rdrrUrr
eer
rrikrki
3
12 )()(4
1)(
And so on…. Not necesarily convergent!
)( )()( 22 rrUrk
Write the Schrödinger equation as:
)),(( r
efeC
ikrrki
Asymptotics:
SUMMARY
)1(
)21(
2
2
2/12
2
2
22
r
rrr
r
r
r
rrr
rrrrrr
The potential is assumed to have short range, i.e. Active only for small r’ :
rr
rikikrrrik eee
1)
rrr
11
ff k
p
r
rk
Asymptotics - Detector is at near infinite r
2)
),(
3)()(4
1)(
f
rkiikr
rki rdrrUer
eer f
Asymptotic excact result:
Still Useless!
The Born approximation:
rdrVem
r
eer rkki
ikrrki f
3)(
2)(
4
2)(
rdrVem
f rkki f 3)(
2)(
2),(
The scattering amplitude is then:
:) The momentum change Fourier transform of the potential!
Use incomming wave instead of )'(r Under integration sign:
Valid when:
1)( rkier
1)()(4
1 3
rdrrUrr
e rrik
Weak potentialsand/or large energies!
rdrVem
f rkkiB
q
f 3)(
2)(
4
2),(
fk
k
q
2sin2
kq
2
00
cos'
0
22
sin)(4
2)( ddedrrrV
mf iqrB
2cos
2sin2sin
dkdq
2cos
0
2sin)(
2drqrrV
q
m
Spheric Symmetric potentials:
Total Cross Section:
ddd
dd )sin(
qdqqfk
dfk
BB
22
02
0
2)(
2)sin()(2
Summary - 1’st. Born Approximation:
rdrVem
f rkkiB
q
f 3)(
2)(
4
2),(
qdqqfk
kB
22
02
)(2
2),( Bf
d
d
fkkq
Best at large energies!
Example - Hard sphere 1. Born scattering:
b R
2
4
2R
d
d
2R
Classical Hard Sphere scattering:
Quantal Hard Sphere potential:
qRRq
mrdrqrRr
q
mf B sin
2sin
22
02
RrrV )(
qRRq
m
d
d 22
2
2sin
2
Depends on angles - but roughly independent when qR << 1 Thats it!
