Non-nucleon metastable excitations in nuclear matter and $e^{-}$ catalysis as a quark-cumulative mechanism for initiating low-energy nuclear chemical processes: phenomenology
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引用次数: 0
Abstract
The present study demonstrates that the mechanism of initiation of low-energy
nuclear chemical processes under conditions of low-temperature non-equilibrium
deuterium and protium-containing glow discharge plasma is similar to the
previously studied cumulative mechanism of initiation of nuclear processes in
the collision of relativistic particles (protons) with target atomic nuclei.
This process results in the formation of high-energy products that
significantly exceed the kinematically resolved region in the pulse space for
two-particle collisions "nucleus-target's nucleus." The cumulative effect in
this case is associated with the initiation of non-nucleonic metastable
excitations in nuclear matter during relativistic collisions leading to the
formation of a group of quarks from different nucleons within the nucleus. In
low-energy nuclear chemical processes, the initiation of quark-cumulative
processes in nuclear matter occurs through interaction of nuclei with electrons
with high kinetic energies on a chemical scale, typically $E_e$ ~ 3-5 eV.
Experiments and available literature data suggest that the metastable
excitations of nuclear matter containing three "free" quarks which occur during
such collisions are associated with quark-cumulative effects, leading to the
radioactive $\alpha$- and $\beta$-decay of elements. This phenomenon is
observed during laser ablation of metals in aqueous media containing
radioactive elements and in the artificial radioactivity of initially
non-radioactive isotopes in cathodes exposed to low-temperature non-equilibrium
deuterium- and protium-containing plasma flows during glow discharge.