The LHC at CERN smashes proton beams to study the fundamental composition of matter and give the world a picture of masses at the subatomic level. The term hadron refers to subatomic composite particles composed of quarks held together by the strong force. Examples of known hadrons are the baryons such as protons and neutrons; hadrons also include mesons such as the pion and kaon. 

Data generated from high-energy particle experiments suggest which versions of current scientific models are more likely to be correct – in particular to choose between the Standard Model and Higgsless model and to validate their predictions. 

The purpose and goals of this paper are to prove the existence of the Fernandes-186-Photon by its relationship with the 144GeV bump observed in the Atlas experiment at CERN.

Employing ratio and proportion where dimensional homogeneity is maintained on both sides of an empirical equation is the method followed utilizing algebraic computation. Elementary charge and magnetic flux are defined for the Fernandes-186-photon mass.

A Fernandes Ether Model will replace the Standard Model and a Higgsless Model. The aitheron produces measures of mass of subatomic particles and atomic mass, not the Higgs Boson. The Higgs Boson is observed but for a fleeting moment under GeV/TeV high acceleration conditions. The Fernandes-186-photon mass has thus been observed indirectly as evidenced by the empirical math computed in this paper.

A source for free energy is embedded in the Fernandes-186-Photon.