Re-evaluation of Fermi’s theory of beta-decay

Guglinski, Wladimir

doi:10.14331/ijfps.2018.330112

Cited by 2 publications

(5 citation statements)

References 45 publications

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“…Gamow's paradox implies that protons and neutrons cannot be bound via strong nuclear force inside the atomic nuclei, as already shown herein. And as the strong force does not play any rule for the stability of the stable atomic nuclei, this means that we don't need to consider it any longer, and we conclude that strong nuclear force does not ex-RSCA of Reid [7]; TSB and TSC of de Tourreil and Sprung [8]; HJ of Hamada and Johnston [9]; TRS of de Tourreil, et al [10]; L1, L2, 2, 4, …, 6 of Mustafa [11]; r1, r3, …, r7 of Mustafa, et al [12]; MHKZ of Mustafa, et al [13]; and a, b, c, …, i of Mustafa [14]. These thirty-three potential models have different deuteron properties, such as deuteron quadrupole moment Q D , D-state probability P D , asymptotic D-state amplitude A D and asymptotic ratio ξ.…”

Section: Strong Nuclear Force Denied By Radius 7fm Of Halo Neutron Inmentioning

confidence: 99%

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The Controversy on the Inverse-Square Law for Coulomb's Interactions

Guglinski¹

2019

Int J At Nucl Phys

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Abdus Salam and his co-workers proposed the concept of strong gravity in the 1960s, as an alternative to the young QCD, so that to solve the puzzles concerning to confinement and asymptotic freedom, not requiring, as occurs in QCD, to abandon the behavior of a force acting from the inverse-square law. At that time asymptotic freedom in QED was observed by some theorists, and by Gerard't Hooft in 1972, whose physical significance however was realized only one year later by David Gross, Frank Wilczek and David Politzer. They "rehabilitated" the Quantum Field Theory, because prior to their discovery it was under suspicion, since Coulomb interactions become infinitely strong at very short distances. But this approach has not so far led to a Grand Unified Theory. Then we are forced to think whether the "rehabilitation" is possible by other alternative, rather than by asymptotic freedom, because there are so many unacceptable puzzles in nuclear physics, that they oblige us to conclude that some of the fundamental principles of the nuclear theory are wrong. Therefore, if some principles of the nuclear theory are wrong, it is possible that the "rehabilitation" must be sought in the atomic nucleus, as proposed herein.

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Section: Strong Nuclear Force Denied By Radius 7fm Of Halo Neutron Inmentioning

confidence: 99%

“…The electric quadrupole moment for the deuteron is calculated in [13], from the graphic on charge tected that 88Rα224 has pear shape [11].…”

Section: Strong Nuclear Force Denied By Radius 7fm Of Halo Neutron Inmentioning

confidence: 99%

The Controversy on the Inverse-Square Law for Coulomb's Interactions

Guglinski¹

2019

Int J At Nucl Phys

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“…And the 2 lepton system (called as the koron) of the 𝜋 (𝑒𝜈 ) koron is, for the first time, reported in the present work. The EC charge distribution of the neutron was explained by introducing the n = (u-e-u)d state for the neutron by Guglinski [7]. The previous explanation using the n = (u-e-u)d state [7] could be compared with the present explanation using the neutron oscillation.…”

Section: Introductionmentioning

confidence: 88%

“…This is called as quark confinement. The strongly confined quarks are mostly located near the surface of the proton as seen in the EC charge distributions of the proton and neutron [6,7] in Fig. 8.…”

Section: Quark Confinementmentioning

confidence: 99%

“…In addition to the asymptotic freedom and quark confinement, the two lepton system (koron) and proton spin crisis are explained in section 5 and section 6, respectively. Two lepton system is discovered by comparing the EC charge distributions of the proton and neutron [6,7] in section 5. And the proton spin crisis [8] is explained from the p(1,0) part of the proton.…”

Section: Introductionmentioning

confidence: 99%

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Asymptotic Freedom, Quark Confinement, Proton Spin Crisis, Neutron Structure, Dark Matters, and Relative force strengths

Hwang¹

2021

Preprint

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The relative force strengths of the Coulomb forces, gravitational forces, dark matter forces, weak forces and strong forces are compared for the dark matters, leptons, quarks, and normal matters (p and n baryons) in terms of the 3-D quantized space model. The quark confinement and asymptotic freedom are explained by the CC merging to the A(CC=-5)3 state. The proton with the (EC,LC,CC) charge configuration of p(1,0,-5) is p(1,0) + A(CC=-5)3. The A(CC=-5)3 state has the 99.6% of the proton mass. The three quarks in p(1,0,-5) are asymptotically free in the EC and LC space of p(1,0) and are strongly confined in the CC space of A(CC=-5)3. This means that the lepton beams in the deep inelastic scattering interact with three quarks in p(1,0) by the EC interaction and weak interaction. Then, the observed spin is the partial spin of p(1,0) which is 32.6 % of the total spin (1/2) of the proton. The A(CC=-5)3 state has the 67.4 % of the proton spin. This explains the proton spin crisis. The EC charge distribution of the proton is the same to the EC charge distribution of p(1,0) which indicates that three quarks in p(1,0) are mostly near the proton surface. From the EC charge distribution of neutron, the 2 lepton system (called as the koron) of the koron is, for the first time, reported in the present work.

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Re-evaluation of Fermi’s theory of beta-decay

Cited by 2 publications

References 45 publications

The Controversy on the Inverse-Square Law for Coulomb's Interactions

The Controversy on the Inverse-Square Law for Coulomb's Interactions

Asymptotic Freedom, Quark Confinement, Proton Spin Crisis, Neutron Structure, Dark Matters, and Relative force strengths

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