Reversal of the Parity Conservation Law in Nuclear Physics

Question of Parity Non-Conservation in Weak Interactions

10.31219/osf.io/9fahx ◽

2021 ◽

Author(s):

zuodong sun

Keyword(s):

Conservation Law ◽

Weak Interactions ◽

Mirror Image ◽

Physical Significance ◽

Β Decay ◽

Membrane Area ◽

Experimental Scheme ◽

Parity Conservation ◽

Wise Choice ◽

The Right

In order to reasonably explain the phenomenon of cell bioelectricity, we proposed the conservation law of cell membrane area, established the ion inequality equation, and therefore paid attention to the mystery of "θ-τ". We researched and analyzed the "θ-τ" mystery, discussed the parity non-conservation in weak interactions, suggested possible experiments to test the parity non-conservation in weak interactions, and gave our research and analysis conclusions: The experimental scheme proposed by C. N. Yang and T. D. Lee in the hypothesis cannot be used as a positive evidence of whether the weak interaction parity is conserved, nor can it directly answer whether θ and τ in the "θ-τ" mystery are the same particle; The Co60 β decay experiment such as C. S. Wu is a pseudo-mirror experiment, and it has not overturned the so-called "parity conservation law" or proved the "parity non-conservation" in weak interactions; The "θ-τ" mystery is a "man-made" mystery. θ and τ are two different particles, which may be the result of the same precursor particle being divided into two. Parity conservation or non-conservation under mirror image has no physical significance. The work of C. N. Yang, T. D. Lee, C. S. Wu et al. have brought quantum physicists from the "Little black house" to the "Big black house" or "smaller black house". The right and wise choice is to go back through "the door that came in". With the development of science today, it is time for some contents to reform from the bottom.

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Radioactive neutron decay flouts “parity conservation” law

Electrical Engineering ◽

10.1109/ee.1958.6445590 ◽

1958 ◽

Vol 77 (1) ◽

pp. 110-112

Keyword(s):

Conservation Law ◽

Neutron Decay ◽

Parity Conservation

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Creation of the nuclear alignment and theG-parity conservation law in weak nucleon currents

Hyperfine Interactions ◽

10.1007/bf02072694 ◽

1987 ◽

Vol 34 (1-4) ◽

pp. 135-138 ◽

Cited By ~ 3

Author(s):

Tadanori Minamisono ◽

Kensaku Matsuta ◽

Yoichi Nojiri

Keyword(s):

Conservation Law ◽

Parity Conservation ◽

Nuclear Alignment

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Nuclear Processes Related to the Ap Stars and the Heaviest Chemical Elements

International Astronomical Union Colloquium ◽

10.1017/s0252921100080520 ◽

1976 ◽

Vol 32 ◽

pp. 169-182

Author(s):

B. Kuchowicz

Keyword(s):

Nuclear Physics ◽

Nuclear Reactions ◽

Chemical Elements ◽

Fission Products ◽

Abundance Pattern ◽

Isotopic Shifts ◽

Processed Material ◽

R Process ◽

Ap Stars ◽

Nuclear Processes

SummaryIsotopic shifts in the lines of the heavy elements in Ap stars, and the characteristic abundance pattern of these elements point to the fact that we are observing mainly the products of rapid neutron capture. The peculiar A stars may be treated as the show windows for the products of a recent r-process in their neighbourhood. This process can be located either in Supernovae exploding in a binary system in which the present Ap stars were secondaries, or in Supernovae exploding in young clusters. Secondary processes, e.g. spontaneous fission or nuclear reactions with highly abundant fission products, may occur further with the r-processed material in the surface of the Ap stars. The role of these stars to the theory of nucleosynthesis and to nuclear physics is emphasized.

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