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Posted
7 hours ago, Mordred said:

Feymann Integrals 

set   c= =1, (D-1), 

momentum o particle p as D dimensional vector D(00) =E/c with D-1 remainder spatial components

Minkowskii scalar product of pa,pb

papb=pμagμνpμb

set propogator of a scalar particle momentum p and mass m

1p2+m2 consider graph G with Next external edges, Nint internal edges and L=loop number for connected graphs

page 16 forwards on Feymann graph rules

Feymann Integrals by Stefan Weinzierl

https://arxiv.org/abs/2201.03593

 

project goal examination of the gauge group langrangians with above reference and applying the QFT creation and annihilation operators and QFT propogators

Electroweak Lanqrangian

L14WαμνWμνα14Wμνμν+Ψ¯¯¯¯iγμDμΨ

W1,2,3μ[ and Bμ are the 4 spin 1 fields 

Covariant derivative

D2=μ+igWτ2ig´2Bμ

W+ andW bosons are expressed as

W±μ=12W1μiW2μ)

γ and Z as

Aμ=Bμ cosθw+W3μ sinθW

Zμ=Bμ sinθw+W3μ cosθW

 

The Cabibbo-Kobayashi-Maskawa matrix

 

 

Why did all the math symbols and structures dissappear? Will have to redo this from scratch 

Posted
2 hours ago, Mordred said:

Why did all the math symbols and structures dissappear? Will have to redo this from scratch 

Hey Mordred, it's good to see you back.

Hope you made your fortune during you long(ish) abscence.

 

I can still see you maths, they haven't disappeared.

But the forum layout has been updated so rolls up a longer post with  "expand" at the bottom.

mordred1.jpg.b4ff002cab97e9f9f3ccdaf0cfa4eb4c.jpg

 

Posted

Unfortunately it dropped the math structure in the fractions and dropped the superscript to subscripts etc. I will simply redo it. At least the Electroweak section and just reference the statements for the Feymann Integrals I want to explore. Maybe a few days though. The reference is one I just recently found and is extremely informative.

Posted (edited)

Electroweak Langrangian

L=14WαμνWμνα14BμνBμν+Ψ¯¯¯¯iγμDμΨ

W1,2,3μ and Bμ

Covariant Derivative

Dμ=μ+igWμτ2ig´2Bμ

mass eigenstates observed in experiments are linear combinations of the electroweak eigenstates. Hence  W and  W+  

W±μ=12(W1μW2μ)

γ and Z are\

Aμ=BmucosθW+W3μsinθW

Zμ=BmusinθW+W3μcosθW

Cabibbo-Kobayashi-Maskawa matrix

d´s´b´VudVcdVtdVusVcsVtsVubVcbVtbdsb

 

symmtric massless

SU(2)LU(1)γ

LW=g2UIL¯¯¯¯¯¯γμ1DiLW+μ+hc

UIL and DIL is a vector in generation space of the up/down quark interaction-eigenstates.

while 1 is a unit-matrix in generation space.

Symmetry break (weak)

LYUIL¯¯¯¯¯¯FUIRH0+DILGDIRH0+hc

VeV  H0=v/2 F and G are Yukawa matrices. 

quark mass terms

MU=Fν2::MD=Gν2

Gauge Interaction

LW=gsqrt2UL¯¯¯¯¯¯γVLDLW+μ+hc

where VL  is the mixing matrix for quarks giving n generations (n*n unitary matrix) with

n2 parameters, in which n(n-1)/2 can be chosen as real angles and n(n+1)/2 are phases

subsequent transformation

v=PUVLPD

v=VudVcdVtdVusVcsVtsVubVcbVtb

 

for 3 generations of quarks

images?q=tbn:ANd9GcQ4MwogPYYC_wMwAAK2rSD

 

 

THE CKM QUARK-MIXING MATRIX 

1) https://escholarship.org/content/qt1jt6c151/qt1jt6c151_noSplash_4cb0f722c2c328730fbac6c5d0971db9.pdf

Feymann Integrals by Stefan Weinzierl

2) https://arxiv.org/abs/2201.03593

PMNS mixing matrix

https://pdg.lbl.gov/2020/reviews/rpp2020-rev-neutrino-mixing.pdf

 

 

Edited by Mordred

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