Nuclear and Atomic Physics

1208 Submissions

[3] viXra:1208.0243 [pdf] replaced on 2012-09-08 16:11:53

The “HIGGS” from Anti-Neutrons and Neutrons

Authors: Glenn A. Baxter
Comments: Eleven pages

The new anti-neutron, first proposed in 2011 [16], and ordinary neutrons, are both without electric charge, and are therefore rather difficult to accelerate and/or impact together in a high energy collider sufficient to cause annihilation, and thus create a 100% energy “Higgs” styled Boson, such Bosons arguably representing all of the mass in the universe. This very high energy impact combination was first suggested during conversation, publicly, by U.K. chemist R. Guy Grantham, MRSC, on 25 August 2011. [18] This writer had proposed, previously [16], a simple universal theory/model of the atom composed of anti-neutrons, electrons, positrons, and neutrinos, which better explains fusion, fission, radioactivity, electromagnetic radiation, gravity, electric force, magnetic force, and the strong force. Dr. D. Sasso’s recent formalisms for electrons, positrons, and photons [19] are adopted herein to better describe the author’s original 2011 anti-neutron model of the atom. [16]
Category: Nuclear and Atomic Physics

[2] viXra:1208.0030 [pdf] replaced on 2013-08-08 04:43:32

Synchronous Interlocking of Discrete Forces: Strong Force Reconceptualised in a NLHV Solution

Authors: Dirk Pons, Arion D. Pons, Aiden J. Pons
Comments: Pages. Published as: Pons, D.J., A.D. Pons, and A.J. Pons, Synchronous interlocking of discrete forces: Strong force reconceptualised in a NLHV solution Applied Physics Research, 2013. 5(5): p. 107-126. DOI:

The conventional requirements for the strong force are that it is strongly attractive between nucleons whether neutral neutrons or positively charged protons; that it is repulsive at close range; that its effect drops off with range. However theories, such as quantum chromodynamics, based on this thinking have failed to explain nucleus structure ab initio starting from the strong force. We apply a systems design approach to this problem. We show that it is more efficient to conceptualise the interaction as interlocking effect, and develop a solution based on a specific non-local hidden-variable design called the Cordus conjecture. We propose that the strong force arises from particules synchronising their emission of discrete forces. This causes the participating particules to be interlocked: the interaction pulls or repels particules into co-location and then holds them there, hence the apparent attractive-repulsive nature of that force and its short range. Those discrete forces are renewed at the de Broglie frequency of the particule. The Cordus theory answers the question of how the strong force attracts the nucleons (nuclear force). We make several novel falsifiable predictions including that there are multiple types of synchronous interaction depending on the phase of the particules, hence cis- and trans-phasic bonding. We also predict that this force only applies to particules in coherent assembly. A useful side effect is that the theory also unifies the strong and electro-magneto-gravitation (EMG) forces, with the weak force having a separate causality. The synchronous interaction (strong force) is predicted to be intimately linked to coherence, with the EMG forces being the associated discoherent phenomenon. Thus we further predict that there is no need to overcome the electrostatic force in the nucleus, because it is already inoperative when the strong force operates. We suggest that ‘strong’ is an unnecessarily limiting way of thinking about this interaction, and that the ‘synchronous’ concept offers a more parsimonious solution with greater explanatory power for fundamental physics generally, and the potential to explain nuclear mechanics.
Category: Nuclear and Atomic Physics

[1] viXra:1208.0006 [pdf] replaced on 2012-12-02 03:57:01

The Radius of the Proton in the Self-Consistent Model

Authors: Sergey G. Fedosin
Comments: 15 pages. Accepted by Hadronic Journal

Based on the notion of strong gravitation, acting at the level of elementary particles, and on the equality of the magnetic moment of the proton and the limiting magnetic moment of the rotating non-uniformly charged ball, the radius of the proton is found, which conforms to the experimental data. At the same time the dependence is derived of distribution of the mass and charge density inside the proton. The ratio of the density in the center of the proton to the average density is found, which equals 1.57.
Category: Nuclear and Atomic Physics