‘Quark flavor’ is a property of ‘strong interaction charge’ and nowhere connected with ‘fermions’ or ‘bosons’. There exists nature friendly ‘integral charge quark flavors’. If a ‘charged quark flavor’ rests in a ‘fermionic container’ it is a ‘quark fermion’. Similarly if a ‘charged quark flavor’ rests in a ‘bosonic container’ it is a ‘quark boson’. Strong interaction charge contains ‘multiple flavors’ and can be called as the ‘hybrid charge quark’. No 3 quark fermions couples together to form a baryon and no 2 quark fermions couples together to form a meson. In super symmetry, quark fermion and quark boson mass ratio is $\Psi \cong 2.262218404$ but not unity. Quark fermions convert into quark baryons and effective quark fermions convert into effective quark baryons. Similarly quark bosons convert into quark mesons. Effective quark baryons generates charged and unstable multi flavor baryons and light quark bosons couples with these charged baryons and generates doublets or triplets. Any two oppositely charged quark mesons generates neutral and unstable mesons. <br> Based on strong nuclear gravity and super symmetry it is suggested that: charged $W$ boson is the super symmetric boson of top quark fermion and charged Higgs boson pair generates the neutralized $Z$ boson. Rest energy of Higgs charged boson is 45586 MeV. It is noticed that charged SUSY Higgs fermion, and nuclear charge radius play a crucial role in the emission of electron in Beta decay. Recently discovered neutral boson of rest energy 120 to 160 MeV seems to be composed of Higgs charged boson and W boson. Its obtained mass is 126 GeV}.
Comments: 2 Pages. Poster presentation in DAE Symposium on Nuclear Physics, December 26-30, 2011, India.
[v1] 2011-12-08 01:23:49
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