Difference between revisions of "Plasma Orbital Expansion of the Electrons in Water"
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− | Brown's Gas boasts a plethora of unusual characteristics that defy current chemistry. It has a cool flame of about 130 degress C (266 degrees F), yet melts steel, brick and many other materials. Confusingly research both confirms and rebuffs many claims about it, leading to a smorgasbord of theories today seeking to explain its unusual properties. One possible theory, currently gaining support even from establishment science, depicts "plasma orbital expansion of the electron in a water molecule". In this process, unlike electrolysis, the water molecule "bends" into a linear, dipole-free geometry. This linear water molecule expands to gain electrons in the d sub-shell, and these extra electrons produce different effects on different target materials. Electrons that scatter at point of contact produce heat based upon electrical conductivity, density and thermal capacity of the material. It will also show why Rydberg clusters are a part of browns gas and how the linear water molecule needs these clusters to survive. This paper will explain this new theory and why it is gaining popularity among scientist in academia.[[Category:Scientific Paper]] | + | Brown's Gas boasts a plethora of unusual characteristics that defy current chemistry. It has a cool flame of about 130 degress C (266 degrees F), yet melts steel, brick and many other materials. Confusingly research both confirms and rebuffs many claims about it, leading to a smorgasbord of theories today seeking to explain its unusual properties. One possible theory, currently gaining support even from establishment science, depicts "plasma orbital expansion of the electron in a water molecule". In this process, unlike electrolysis, the water molecule "bends" into a linear, dipole-free geometry. This linear water molecule expands to gain electrons in the d sub-shell, and these extra electrons produce different effects on different target materials. Electrons that scatter at point of contact produce heat based upon electrical conductivity, density and thermal capacity of the material. It will also show why Rydberg clusters are a part of browns gas and how the linear water molecule needs these clusters to survive. This paper will explain this new theory and why it is gaining popularity among scientist in academia. |
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+ | [[Category:Scientific Paper|plasma orbital expansion electrons water]] |
Latest revision as of 10:54, 1 January 2017
Scientific Paper | |
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Title | Plasma Orbital Expansion of the Electrons in Water |
Read in full | Link to paper |
Author(s) | Chris Eckman |
Keywords | {{{keywords}}} |
Published | 2010 |
Journal | Proceedings of the NPA |
Volume | 7 |
No. of pages | 4 |
Pages | 141-144 |
Read the full paper here
Abstract
Brown's Gas boasts a plethora of unusual characteristics that defy current chemistry. It has a cool flame of about 130 degress C (266 degrees F), yet melts steel, brick and many other materials. Confusingly research both confirms and rebuffs many claims about it, leading to a smorgasbord of theories today seeking to explain its unusual properties. One possible theory, currently gaining support even from establishment science, depicts "plasma orbital expansion of the electron in a water molecule". In this process, unlike electrolysis, the water molecule "bends" into a linear, dipole-free geometry. This linear water molecule expands to gain electrons in the d sub-shell, and these extra electrons produce different effects on different target materials. Electrons that scatter at point of contact produce heat based upon electrical conductivity, density and thermal capacity of the material. It will also show why Rydberg clusters are a part of browns gas and how the linear water molecule needs these clusters to survive. This paper will explain this new theory and why it is gaining popularity among scientist in academia.