Download Lecture 20

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Photon wikipedia , lookup

Ising model wikipedia , lookup

Ferromagnetism wikipedia , lookup

Magnetochemistry wikipedia , lookup

Relativistic quantum mechanics wikipedia , lookup

Quantum electrodynamics wikipedia , lookup

Transcript
Lecture 20: Mar 29th 2012
Reading Griffiths chapter 7
HW due next Thursday: 7.37, 7.39
Calculate the e+e-  +- CM frame matrix element. In the ultra-relativistic limit show
that it obeys the s,t,u crossing relationship with e--  e-1) Feynman rules for iM
a) Draw a diagram labeling all the incoming and outgoing momentum and spins. Use
arrows to indicate particles (with direction of time) and antiparticles (opposite direction
of time) and internal lines (preserving continuity of the direction of flow). Note down
which spins are known and which will be summed over (final or internal state spins) or
averaged over (initial state spins if unknown).
b) Write down spinors for particles and antiparticles. u for incoming electrons and u for
outgoing electrons. u for incoming positrons and  for outgoing positrons. e m for
incoming photons and e m * for outgoing photons. For instance for an incoming electron,
s3
1, we write us1 (p1 ) and for an outgoing electron, 3, u ( p3 )
c) Vertex factors of ige, use a different index for each vertex term.
Each vertex represents a separate interaction and has its own index
As an example with particles a vertex factor is written between the outgoing (first) and
incoming (last) particle to form a current term.
s3
b and c form the current terms, example u ( p3 ) us1 (p1 ), which will reduce to factors
proportional to momentum just as in our scalar particle transition rate. This is the basic
unit for a particle in transition and is called a particle current, i.e. the J we derived.
Where there is an initial or final state photon at the vertex the vertex factor will be
summed over  with the photon if there is one. e m = e/ .
d) Propagators for the photons or electrons/positrons: -ig/q2,
i(q + m)/(q2 - m2)
Note in the photon propagator case the g matrix converts  to  so it is summed with
 of the first current. The propegator is what relates the two interactions in this case.
In the case of the electron propagator each current has a photon which is summed with
the  vertex and the propagator has it’s own sum over q, so no further sums have to be
done to get a scalar result for the matrix element probability. q is often written as q/
e) Add an integral over the internal four momentum d4q/(2)4 and a four dimensional
delta function for each vertex and use one to integrate over the internal four momentum
and cancel the other since it corresponds to overall four momentum conservation.
f) antisymmetrization. Crossed diagrams will exist for identical sets of particles in the
final state. The second diagram will get a negative sign (Fermi statistics).
Diagrams can have their electrons moved from the initial to the final state where they
occur as a positron producing an equivalent in probability diagram ( a type of crossing
symmetry). To have a consistent convention you have to be careful about the signs in
those cases.
2) Examples:
Electron-electron scattering: Standard diagram and crossed diagram
-iM = ò u s3 (p3 )igeg m us1 (p1 )
-igmn
q2
u s4 (p4 )igeg n us2 (p2 ) ( 2p ) d 4 ( p1 - p3 - q) ( 2p ) d 4 ( p2 + q - p4 )
4
4
d 4q
( 2p )
4
and a crossed diagram terms with a negative sign
-ig
4
4
d 4q
-iM = - ò u s 4 (p4 )igeg m us1 (p1 ) 2mn u s3 (p3 )igeg n us2 (p2 ) ( 2p ) d 4 ( p1 - p4 - q) ( 2p ) d 4 ( p2 + q - p3 )
4
q
( 2p )
Use the integration over one delta function to evaluate q. Cancel the other one.
Considering the case where we start with un-polarized electrons, we can drop the spin
labels and remember that we will have to average over the initial states and sum over the
final states in the end.
M=
-ge2
( p1 - p3 )
m
2 [ u (3)g u(1)][ u (4)g m u(2)] +
ge2
( p1 - p4 )
2
[ u(3)g
m
u(2)][ u (4)g m u(1)]
Electron positron scattering: Standard diagram and annihilation diagram. Now that we
are used to the form of the matrix element we can skip straight to the second step.
M=
-ge2
( p1 - p3 )
éu(3)g m u(1)ùéën (2)g mn (4)ùû +
û
2ë
ge2
( p1 + p2 )
2
én (2)g m u(1)ùéëu(3)g mn (4)ùû
ë
û
Note that in the first term the current electron to positron involves only initial or final
state particles respectively. When writing down the terms we always put the adjoint term
of the current first so that when multiplied by other term you get a scalar probability.
Note the change in sign for the second term. The diagrams can be created from each
other by crossing electrons and positrons from the initial to the final state.
We will consider diagrams with photons later.
3) Madelstam variables.
Define the Madelstam variables.
s = ( p1 + p2 ) = p12 + p23 + 2 p1 · p2 = 2m 2 + 2E1E2 - 2 p cosq12
2
2
= 2m 2 + 2(m 2 + p ) + 2 p = 4( p + m 2 ) = 4(p2 + m 2 )
2
2
2
,
t = ( p1 - p3 ) = p12 + p32 - 2 p1 · p3 = 2m 2 - 2E1E3 + 2 p cosq13
2
2
= 2m 2 - 2(m 2 + p ) + 2 p cosq13 = -2 p (1- cosq13 ) = -2 p2 (1- cosq )
2
2
2
and
2
s = ( p1 + p2 ) = 4( p2 + m 2 ),
2
q
t = ( p1 - p3 ) = -2 p2 (1- cosq ) = -4 p2 sin 2 , and
2
q
u = ( p1 - p4 ) = -2 p 2 (1+ cosq ) = -4 p2 cos2 ,
2
where p is the 3 momentum magnitude for incident particle 1 and theta the angle to the
scattered particle 3.
Note: it is important to use a consistent notation when defining theta.
Note: assumes the masses are the same. Often used when the masses are negligible.
2
Then
Electron-electron scattering: Standard diagram and crossed diagram
M=
2
-ge2 é
m
ùéëu(4)g m u(2)ùû + ge éëu(3)g m u(2)ùûéu(4)g m u(1)ù
u(3)
g
u(1)
ë
û
ë
û
t
u
Electron positron scattering: Standard diagram and annihilation diagram.
-ge2 é
ge2 é
m
m
ù
ù
é
ù
M=
ëu(3)g u(1)ûën (2)g mn (4)û + ën (2)g u(1)ûéëu(3)g mn (4)ùû
t
s
4) Non relativistic scattering of unpolarized identical particles
Before tackling the more “complex” relativistic case where we must evaluate all the
matrix and vector multiplications it is instructive to consider a non relativistic case where
the matrix math simplifies.
æu ö
u( p)1 = N ç A ÷,
è uB ø
N=(|E|+m)
æ 1ö
uA = ç ÷,
è 0ø
uB =
æ1ö
1
1 æ pz ö
( p × s )ç ÷ =
ç
÷,
E+m
è0ø E + m è px + ipy ø
æu ö
u( p) 2 = N ç A ÷,
è uB ø
æ 0ö
uA = ç ÷,
è 1ø
uB =
æ0ö
1
1 æ px - ipy ö
( p × s )ç ÷ =
ç
÷
E+m
è1ø E + m è - pz ø
If p<<m then all the p terms in the spinors go to 0 because they are divided by m. Then
u s1g m us3 = 2mds1,s3 using u iuj = 2mij,= 1,2 spins and the fact that only the 0 matrix will
contribute since the other are anti-block diagonal.
Then using the result
M=
2
-ge2 é
m
ùéëu(4)g m u(2)ùû + ge éu(4)g m u(1)ùéëu(3)g m u(2)ùû
u(3)
g
u(1)
ë
û
ë
û
t
u
Now consider all the various spin combinations so we can later average over the initial
states and sum over the final states.
æ1 1 1 1ö
æ -1 -1 -1 -1 ö
æ1 1 ö
M (1, 2 ® 3, 4) M ç , ® , ÷ = M ç , ® , ÷ = -4ge2 me2 ç - ÷
è2 2 2 2ø
è2 2
èt uø
2 2ø
identical particles in the end state so both the t and u channel diagrams contribute
and
Note that the summation condition over and u does not allow this interaction to flip the
spins. This is expected at first order for slow moving electrons, since they will only
interact via the electric field, which we know from the atom does not continually flip
spins. However, at higher energy spin flips are possible because the moving electrons
are starting to represent a strong current and can interact via the magnetic part of the
field. Also for the first set of spins we have true identical particles we must include
crossed diagrams in M. In the second two matrix elements we also do not flip the spins
since that would create a sum over
and u that is 0, but the crossed u channel diagram
leaves particle 4 with the spin of particle 1 so that matrix multiplication is not 0.
To evaluate the full matrix element for unpolarized we have to average over the number
of initial spin states and sum over the final spin states.
M =
2
1
2
Mi
å
(2s1 +1)(2s2 +1) i
The probability will be proportional to the matrix element times it’s complex conjugate.
Each of the three processes above is independent so we will square each and then add
them. Averaging over initial spin states introduces two factors or ½. Summing over the
final states each matrix element there are three distinct possibilities that occur twice each.
2
2 éæ 1
1
1ö 1 1 ù
2
M = 2( 4me2 ge2 ) êç - ÷ + 2 + 2 ú
4
u û
ëè t u ø t
substituting in our expressions for t and u and simplifying
M = 8(m g
2
)
2 2 2
e e
é
ù
ê
ú
2
1
1
1
+
ê
ú
16 p 4 ê sin 4 q cos4 q sin 2 q cos2 q ú
ë
2
2
2
2û
and putting this in:
d/d = (1/8)2 |M|2 pi/pf 1/E2
where in the non relativistic limit E = 2me
This type of result will be typical even in the full treatment in that we will end up with a
number of s, t and u type scattering or annihilation terms.