Nuclear and Atomic Physics

1111 Submissions

[4] viXra:1111.0064 [pdf] submitted on 18 Nov 2011

Femtotechnology: Stability of AB-needles. Fantastic Properties and Application

Authors: A.A. Bolonkin
Comments: 19 pages

In article �Femtotechnology: Nuclear AB-Matter with Fantastic Properties� *1+ American Journal of Engineering and Applied Sciences. 2 (2), 2009, p.501-514. (http://www.scribd.com/doc/24045154) author offered and consider possible super strong nuclear matter. But many readers asked about stability of the nuclear matter. It is well known, the conventional nuclear matter having more 92 protons or more 238 nucleons became instability. In given work the author shows the special artificial forms of nuclear AB-matter make its stability and give the fantastic properties. For example, by the offered AB-needle you can pierce any body without any damage, support motionless satellite, reach the other planet, researched Earth�s interior. These forms of nuclear matter are not in Nature now, but nanotubes also is not in Nature. That is artificial matter is made men. The AB-matter also is not now, but research and investigation their possibility, stability and properties are necessary for creating them.
Category: Nuclear and Atomic Physics

[3] viXra:1111.0039 [pdf] submitted on 10 Nov 2011

Decay Modes of Excited 4he Below the Fragmentation Levels

Authors: A. Meulenberg, K P Sinha
Comments: 10 pages

Three reasons are given to dispute the claims of numerous experimenters that higher-than-expected heat and radiation are obtained from nuclear fusion of deuterium atoms at room temperature: 1) the inability of two low-energy protons or deuterons to penetrate the mutual Coulomb barrier; 2) the production of heat in excess of that possible for the measured particulate radiation, and 3) the high levels of 4He measured (much beyond that permitted by present nuclear physics models). The first has been addressed earlier. This paper discusses the second and how it leads to an understanding of a critical mechanism behind low-energy nuclear reactions.
Category: Nuclear and Atomic Physics

[2] viXra:1111.0023 [pdf] replaced on 2014-12-17 03:28:54

Weak Interaction and the Mechanisms for Neutron Stability and Decay

Authors: Dirk J. Pons, Arion D. Pons, Aiden J. Pons
Comments: 15 Pages. Citation: Pons, D. J., Pons, A. D., and Pons, A. J., Weak interaction and the mechanisms for neutron stability and decay Applied Physics Research, 2015. 7(1): p. 1-11. DOI: http://dx.doi.org/10.5539/apr.v7n1p1

Purpose – The decay of the neutron is well known from the perspective of empirical quantification, but the ontological explanations are lacking for why the neutron should be stable within the nucleus and unstable outside. A theory is developed to explain the reasons for decay of the free neutron and stability of the bonded neutron. Method – The Cordus theory, a type of non-local hidden-variable (NLHV) design, provided the mathematical formalism of the principles for manipulating discrete forces and transforming one type of particule into another. This was used to determine the structures of the W and Z bosons, and the causes of neutron decay within this framework. Findings - The stability of the neutron inside the nucleus arises from the formation of a complementary bound state of discrete forces with the proton. The neutron is an intermediary between the protons, as the discrete forces of the protons are otherwise incompatible. This bond also gives a full complement of discrete forces to the neutron, hence its stability within the nucleus. The instability of the free neutron arises because its own discrete field structures are incomplete. Consequently it is vulnerable to external perturbation. The theory predicts the free neutron has two separate decay paths, which are mixed together in the β- process, the first determined by the local density of the fabric, and the second by the number of neutrinos encountered. The exponential life is recovered. The internal structures of the W bosons are determined. Implications – The W bosons are by-products from the weak decay process, and do not cause the decay. The weak decay is shown to be in the same class of phenomenon as annihilation, and is not a fundamental interaction. Originality – A novel theory has been constructed for the decay process, using a NLHV mechanics that is deeper than quantum theory. This new theory explains the stability-instability of the neutron and is consistent with the new theory for the stability of the nuclides.
Category: Nuclear and Atomic Physics

[1] viXra:1111.0022 [pdf] replaced on 2014-04-17 18:36:11

Beta Decays and the Inner Structures of the Neutrino in a NLHV Design

Authors: D.J. Pons, A.D. Pons, A.J. Pons
Comments: 21 Pages. Pons, D. J., Pons, A., D., & Pons, A., J. (2014). Beta decays and the inner structures of the neutrino in a NLHV design. Applied Physics Research, 6(3), 50-63. doi:http://dx.doi.org/10.5539/apr.v6n3p50 (alternative http://vixra.org/abs/1111.0022)

A novel conceptual theory is developed for the beta decay and electron capture processes, based on the specific non-local hidden-variable (NLHV) design provided by the Cordus theory. A new mechanics is sketched out for the interactions of particules through their discrete forces, and is a deeper level representation of Feynman diagrams. The new mechanics is able to correctly predict the outcomes of the decay processes, beta minus, beta plus, electron capture. It predicts specific NLHV structures for the neutrino and antineutrino. The velocity and unique spins of the neutrino species may then be explained as a consequence of the hidden structures.
Category: Nuclear and Atomic Physics