FEYNMAN’S ADVANCED WAVES UNIFY THE SCALAR HIGGS BOSON WITH THE SUPPOSEDLY UNRELATED NON-SCALAR GRAVITON

Recently added: "Main two clarifications to my submission" - There are two points which may need to be clarified - <br>First, in relation to E=0 (second last paragraph in SECTION 2 – QUANTUM SPIN, ADVANCED WAVES, AND SPECIAL RELATIVITYSecond, in relation to quantum spin/vector/tensor/scalar (last and third last paragraphs in SECTION 2 – QUANTUM SPIN, ADVANCED WAVES, AND SPECIAL RELATIVITY<br>This article suggests existence of the graviton was actually confirmed by discovery of the supposedly unrelated Higgs boson on 4 July 2012. First suspected to exist in the 1960s, more studies are still needed to verify with higher precision that the discovered particle has all of the properties predicted. The need for further studies is in line with this article’s proposal that the Higgs boson and field are not what they’re assumed to be ie the Higgs field is believed to give mass to some particles (quarks and charged leptons plus the weak nuclear force’s W and Z bosons) while the Higgs boson is said to be the field’s quantum excitation. The proposal here is that photon-graviton interactions, and thus the electromagnetic-gravitational fields - more precisely, m = (D subscript 1+0), (S sub M, K sub 8), (n x 10 exponent 12.γ sub s/G sub s) - are responsible for ALL mass, and the Higgs boson (whether it exists in one or several forms) is a “leftover” from the advanced waves formed from photons and gravitons (see the Wheeler-Feynman absorber theory and the Transactional Interpretation of Quantum Mechanics). Being left-over from gravitational waves, the Higgs boson is obviously related to the graviton – and if this article is correct, discovery of the former particle makes existence of the latter absolutely essential (confirms its existence). As well: in my thoughts, Wolfgang Pauli’s 1924 approach to quantum spin - and Albert Einstein’s 1919 paper "Do gravitational fields play an essential role in the structure of elementary particles?" - both played important parts in uniting quantum mechanics and gravity into the phenomenon of matter. On the way to this union, Einstein’s dream of uniting electromagnetism with gravitation seems to have supersymmetrically fallen into place. <br>