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HADRONIC MATHEMATICS, MECHANICS AND CHEMISTRY 19 Figure 1.6. Another illustration of the second major scientific imbalance studied in this monograph, the dramatic structural differences between exterior and interior dynamical systems, here represented with the Solar system (top view) and the structure of Jupiter (bottom view). Planetary systems have a Keplerian structure with the exact validity of the Galilean and Poincaré symmetries. By contrast, interior systems such as planets (as well as hadrons, nuclei and stars) do not have a Keplerian structure because of the lack of the Keplerian center. Consequently, the Galilean and Poincaré symmetries cannot possibly be exact for interior systems in favor of covering symmetries and relativities studied in this monograph. In the transition to particles the situation remains the same as that at the classical level. For instance, nuclei do not have nuclei and, therefore, nuclei are not Keplerian systems. Similarly, the Solar system is a Keplerian system, but the Sun is not. At any rate, any reduction of the structure of the Sun to a Keplerian system directly implies the belief in the perpetual motion within a physical medium, because electrons and protons could move in the hyperdense medium in the core of a
20 RUGGERO MARIA SANTILLI star with conserved angular momenta, namely, a belief exiting all boundaries of credibility, let alone of science. The above evidence establishes beyond credible doubt the following: THEOREM 1.2.2 [10b]: Galileo’s and Poincaré symmetries are inapplicable for classical and operator interior dynamical systems due to the lack of Keplerian structure, the presence of contact, zero-range, non-potential interactions, and other reasons. Note the use of the word “inapplicable”, rather than “violated” or “broken”. This is due to the fact that, as clearly stated by the originators of the basic spacetime symmetries (rather than their followers of the 20-th century), Galileo’s and Poincaré symmetries were not built for interior dynamical conditions. Perhaps the biggest scientific imbalance of the 20-th century has been the abstraction of hadronic constituents to point-like particles as a necessary condition to use conventional spacetime symmetries, relativities and quantum mechanics for interior conditions. In fact, such an abstraction is at the very origin of the conjecture that the undetectable quarks are the physical constituents of hadrons (see Section 1.2.7 for details).. Irrespective of whether we consider quarks or other more credible particles, all particles have a wavepacket of the order of 1 F = 10 −13 cm, that is, a wavepacket of the order of the size of all hadrons. Therefore, the hyperdense medium in the interior of hadrons is composed of particles with extended wavepackets in conditions of total mutual penetration. Under these conditions, the belief that Galileo’s and Poincaré symmetries are exactly valid in the interior of hadrons implies the exiting from all boundaries of credibility, let alone of science. The inapplicability of the fundamental spacetime symmetries then implies the inapplicability of Galilean and special relativities as well as of quantum nonrelativistic and relativistic mechanics. We can therefore conclude with the following: COROLLARY 1.2.2A [10b]: Classical Hamiltonian mechanics and related Galilean and special relativities are not exactly valid for the treatment of interior classical systems such as the structure of Jupiter, while nonrelativistic and relativistic quantum mechanics and related Galilean and special relativities are not exactly valid for interior particle systems, such as the structure of hadrons, nuclei and stars. Another important scope of this monograph is to show that the problem of the exact spacetime symmetries applicable to interior dynamical systems is not a mere academic issue, because it carries a direct societal relevance. In fact, we shall show that broader spacetime symmetries specifically built for interior
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Page 3 and 4: iii This volume is dedicated to the
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Page 7 and 8: Contents Foreword Preface Legal Not
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Page 41 and 42: 24 RUGGERO MARIA SANTILLI The decay
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Page 45 and 46: 28 RUGGERO MARIA SANTILLI massive e
Page 47 and 48: 30 RUGGERO MARIA SANTILLI Moreover,
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Page 75 and 76: 58 RUGGERO MARIA SANTILLI The above
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70 RUGGERO MARIA SANTILLI on physic
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72 RUGGERO MARIA SANTILLI the Ameri
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74 RUGGERO MARIA SANTILLI (Rodrigue
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76 RUGGERO MARIA SANTILLI In the ab
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78 RUGGERO MARIA SANTILLI devoted t
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80 RUGGERO MARIA SANTILLI The repre
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82 RUGGERO MARIA SANTILLI This sect
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84 RUGGERO MARIA SANTILLI with Birk
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86 RUGGERO MARIA SANTILLI genomathe
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88 RUGGERO MARIA SANTILLI By rememb
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90 RUGGERO MARIA SANTILLI Evidently
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92 RUGGERO MARIA SANTILLI Nonunitar
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94 RUGGERO MARIA SANTILLI = (U × A
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96 RUGGERO MARIA SANTILLI 4) The so
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98 RUGGERO MARIA SANTILLI However,
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100 RUGGERO MARIA SANTILLI form A
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102 RUGGERO MARIA SANTILLI It shoul
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104 RUGGERO MARIA SANTILLI Figure 1
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106 RUGGERO MARIA SANTILLI Referenc
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108 RUGGERO MARIA SANTILLI [44] L.
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110 RUGGERO MARIA SANTILLI [87] R.
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112 RUGGERO MARIA SANTILLI General
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116 RUGGERO MARIA SANTILLI [86] Chu
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118 RUGGERO MARIA SANTILLI [120] H.
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120 RUGGERO MARIA SANTILLI [154] S.
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122 RUGGERO MARIA SANTILLI [189] M.
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126 RUGGERO MARIA SANTILLI [259] V.
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138 RUGGERO MARIA SANTILLI [478] G.
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140 RUGGERO MARIA SANTILLI [515] J.
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142 RUGGERO MARIA SANTILLI [552] N.
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144 RUGGERO MARIA SANTILLI [587] A.
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146 RUGGERO MARIA SANTILLI [621] K.
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148 RUGGERO MARIA SANTILLI [657] N.
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150 RUGGERO MARIA SANTILLI [690] J.
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152 RUGGERO MARIA SANTILLI [723] T.
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154 RUGGERO MARIA SANTILLI implies
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156 RUGGERO MARIA SANTILLI nature,
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Index Lagrange equations, truncated
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INDEX 161 Iso-hamiltonian, 265 Iso-
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INDEX 163 Lorentz-Santilli isosymme
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