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HK: Fachverband Physik der Hadronen und Kerne

HK 72: Poster

HK 72.59: Poster

Thursday, March 14, 2024, 17:15–18:45, HBR 14: Foyer

Significance of the number space Q and the coordinate system for energy ratios of elementary particles — •Helmut Christian Schmidt — LMU München

For energy relations, as in the GR, a system of 3 objects, each with 3 spatial coordinates (ϕ,r,θ) and the common time, is sufficient. The quantum information from these 10 independent parameters results in a polynomial P(2). Each measurement consists of coincidences of revolutions qπ q ∈ Q. A transformation into P(2π) provides the energy ratios. P(2π) is compatible with quantum theory and GR.

E.g. neutron:

E_p = (2π)⁴ + (2π)³ + (2π)²

E_e = −((2π)¹ + (2π)⁰ + (2π)⁻¹)

E_{measuring− device}=2(2π)⁻²+2(2π)⁻⁴−2(2π)⁻⁶
Christoffel-Symbol

E_time = 6(2π)⁻⁸

m_neutron/m_e = E_p + E_e + E_measurement + E_time = 1838.6836611

measured: 1838.68366173(89) m_e

Neutrinos correspond to ν_τ=π, ν_µ=1, ν_e=π⁻¹.

h G_N c⁵ s⁸/m¹⁰ √π⁴ − π² − π⁻¹ −π⁻³ = 0,999991

A photon is made up of neutrinos and can be viewed as two entangled electrons e⁻ and e⁺. The charge results in an energy ratio E_C.

E_C=−π¹+2π⁻¹+π⁻³−2π⁻⁵+π⁻⁷−π⁻⁹ +π⁻¹²

m_proton = m_neutron + E_C m_e = 1836.15267363 m_e

An approach to an algorithm for calculating the muon and tauon mass is presented.

Keywords: neutron mass; proton mass; muon mass; ur-objects; Ratios of energies