CP Violation in Kaon Decay in the Scalar Strong Interaction Hadron Theory

ABSTRACT

CP conservation and violation in neutral kaon decay are considered from a first principles’ theory, recently published as “*Scalar Strong Interaction Hadron Theory*”. The arbitrary phase angle relating *K*^{0} and ^{0} in current phenomenology is identified to be related to the product of the relative energy to the relative time between the *s* and *d* quarks in these kaons. The argument of the CP violating parameter ? is predicted to be 45? without employing measured data. The *K*^{0}_{S} decay rate is twice the *K*^{0}_{L} -*K*^{0}_{S} masss difference, in near agreement with data, and both are proportional to the square of the relative energy 29.44 eV. Any pion from *K*^{0}_{L} decay will also have a mass shift of ≈1.28 × 10^{-5} eV. The present first principles’ theory is consistent with CP conservation. To achieve CP violation, the relative time cannot extend to both +∞ and -∞ but is bounded in at least one direction. The values of these bounds lie outside the present theory and it is unknown how they can be brought forth. -B^{0} mixing is also considered and the relative energy is 663.66 eV.

CP conservation and violation in neutral kaon decay are considered from a first principles’ theory, recently published as “

Cite this paper

F. Hoh, "CP Violation in Kaon Decay in the Scalar Strong Interaction Hadron Theory,"*Journal of Modern Physics*, Vol. 3 No. 10, 2012, pp. 1562-1571. doi: 10.4236/jmp.2012.310193.

F. Hoh, "CP Violation in Kaon Decay in the Scalar Strong Interaction Hadron Theory,"

References

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[2] T. D. Lee, “Particle Physics and an Introduction to Field Theory,” Harwood Academic Publisher, Newark, 1981.

[3] K. Kleinknecht, “Uncovering CP Violation: Experimental Clarification in the Neutral K Meson and B Meson Systems,” Springer, Berlin, 2003.

[4] F. C. Hoh, “Scalar Strong Interaction Hadron Theory,” Nova Science Publishers, New York, 2011. https://www.novapublishers.com/catalog/product_info.php?products_id=27069

[5] F. C. Hoh, “Scalar Strong Interaction Hadron Theory (SSI)—Kaon and Pion Decay,” In: C. J. Hong, Ed., The Large Hadron Collider and Higgs Boson Research, Nova Science Publishers, New York, 2011, pp. 1-77.

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[1] J. Beringer, et al., “Particle Data Group,” Physical Review D, Vol. 86, No. 1, 2012, Article ID: 010001. doi:10.1103/PhysRevD.86.010001

[2] T. D. Lee, “Particle Physics and an Introduction to Field Theory,” Harwood Academic Publisher, Newark, 1981.

[3] K. Kleinknecht, “Uncovering CP Violation: Experimental Clarification in the Neutral K Meson and B Meson Systems,” Springer, Berlin, 2003.

[4] F. C. Hoh, “Scalar Strong Interaction Hadron Theory,” Nova Science Publishers, New York, 2011. https://www.novapublishers.com/catalog/product_info.php?products_id=27069

[5] F. C. Hoh, “Scalar Strong Interaction Hadron Theory (SSI)—Kaon and Pion Decay,” In: C. J. Hong, Ed., The Large Hadron Collider and Higgs Boson Research, Nova Science Publishers, New York, 2011, pp. 1-77.

[6] D. B. Lichtenberg, “Unitary Symmetry and Elementary Particles,” Academic Press, Waltham, 1978.