Authors :
Noriyuki Kodama
Volume/Issue :
Volume 7 - 2022, Issue 1 - January
Google Scholar :
http://bitly.ws/gu88
Scribd :
https://bit.ly/3FsDdEG
Abstract :
I proposed the Conceptualized Transmutation
reactor to add protons and neutrons to the element.
Previous transmutation reactor just adds protons, with
small D2 or small H2 based on electron deep orbit theory,
which shows that element can have the deeper orbit than
n=0, which orbit is at a few femto meter from the nucleus,
so the cold fusion occurs for D2 gas supply, so, I proposed
the conceptualized reactor with H2 gas to prevent cold
Fusion. Usually, nuclear experiments on transmutation
need both neutron and proton addition, Thus I propose
the experiment on Conceptualized transmutation reactor.
The mechanism is based on Cold Fusion and gas is H2 and
it is important to control the metal temperature as low as
possible to emit small H2(die-neutron), and for the small
proton(neutron) creation, the higher metal temperature is
used to breakdown the covalent bond of small H2(p-p pair
in electron deep orbit) to create neutron (proton-electron
pair in Electron deep orbit). This transmutation reactor
enables the detailed study of the chemical and physical
property of the super heavy metals. Another
conceptualized reactor uses the compression of covalent
bond of metal-none metal element to study the super
heavy element metal, starting metal is as heavy as
possible so Pb is option and heaviest none metal element
is Br and the resulting transmuted element is Ts
(Tennessine), which decays to Mc (Moscovium), which
attract attentions. The Conceptualized reactor has
drawback due to the poor mechanism so I hope the
researchers study the mechanism of compression of
covalent bonding efficiently.
Keywords :
Plutonium Moscovium Tennessine transmutation stability island Cold Fusion.
I proposed the Conceptualized Transmutation
reactor to add protons and neutrons to the element.
Previous transmutation reactor just adds protons, with
small D2 or small H2 based on electron deep orbit theory,
which shows that element can have the deeper orbit than
n=0, which orbit is at a few femto meter from the nucleus,
so the cold fusion occurs for D2 gas supply, so, I proposed
the conceptualized reactor with H2 gas to prevent cold
Fusion. Usually, nuclear experiments on transmutation
need both neutron and proton addition, Thus I propose
the experiment on Conceptualized transmutation reactor.
The mechanism is based on Cold Fusion and gas is H2 and
it is important to control the metal temperature as low as
possible to emit small H2(die-neutron), and for the small
proton(neutron) creation, the higher metal temperature is
used to breakdown the covalent bond of small H2(p-p pair
in electron deep orbit) to create neutron (proton-electron
pair in Electron deep orbit). This transmutation reactor
enables the detailed study of the chemical and physical
property of the super heavy metals. Another
conceptualized reactor uses the compression of covalent
bond of metal-none metal element to study the super
heavy element metal, starting metal is as heavy as
possible so Pb is option and heaviest none metal element
is Br and the resulting transmuted element is Ts
(Tennessine), which decays to Mc (Moscovium), which
attract attentions. The Conceptualized reactor has
drawback due to the poor mechanism so I hope the
researchers study the mechanism of compression of
covalent bonding efficiently.
Keywords :
Plutonium Moscovium Tennessine transmutation stability island Cold Fusion.
