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New Theories / Do I understand neutrinos?
« on: 09/11/2021 14:29:46 »
The Darkness Of The Neutrino;
In the year 1930 A.D. Wolfgang Pauli predicted the existence of an ephemeral undiscovered particle hypothesized to be carrying away missing energy from decaying radioactive nuclei. This particle was eventually detected by Reines and Cowan in 1956 and dubbed by Enrico Fermi the neutrino. The LINE hypothesis proposes that like all particles, the neutrino is a distinct type of particle and is also derivative of other particle types be they known or unknown. The neutrino is an intermediate particulate Planck Hole (PH) regime between the debytons (dark matter) and leptons. Like a lepton such as the electron, the neutrino hosts a pyrine structure that can retain information as mass but with a greater native PH bandwidth than any lepton. Additionally, like the debytons, the neutrino hosts a QE channel to metamatter but with a lesser PH bandwidth than the debytons. Unlike baryonic and leptonic pyrine, the neutrino pyrine sequesters no debyton particles due to its diminutive information accumulation as mass and therefor has undetectable charge. Some minimum amount of mass is required to produce the information circulation dynamics called charge, the strong force, and to sequester a proportional quantity of debytonic particles to produce the accompanying Einsteinian gravitation (G). This places the neutrinos’ information teleportation bandwidth natively higher by convention on the QE spectrum than the leptons but lower than the debytons. This structure makes the neutrino the intermediate link between leptonic (normal) matter and debytonic (dark) matter.
As neutrinos transition through space, its mass oscillates by the neutrino pyrines’ interaction with free debytonic (dark) matter particles as both travel through space. The lower PH bandwidth of baryonic and leptonic pyrine within protons and neutrons and electrons accumulates more information as mass due to their pyrine’s lower ground-state PH dilation. The ground-state PH dilation is the native PH bandwidth, with zero debyton particle sequestration within the central PH regime around which particulate pyrine form. Each debyton particle sequestered within the pyrines’ circulating information channel increases the QE bandwidth and gravitation of the pyrine and the particle it projects into the subatomic realm. Baryonic pyrine’s diminutive native drain of information into the metaverse accumulates more information within its pyrine, ergo; greater mass. This increased mass is able to sequester a normal quantity of free debytons to produce a normal Newtonian/Einsteinian gravitational potential (G). This increased baryonic information outflow called gravitation comes via the increased PH dilation of each additional sequestered debyton particles QE channel with metamatter. However, when there is insufficient mass accumulation around a ground-state particulate PH regime, a particle cannot accommodate the sequestration of a normal Einsteinian quantity of debytons within its pyrine structure. Consequently, free debytons that would normally become trapped within pyrine for a time or for an entire universal transition cycle, instead buffet and attenuate the ground-state PH bandwidth of vulnerable particulate PH regimes such as the neutrinos’ as both travel through space.
Each debyton-neutrino interaction causes a proportional attenuation of the neutrinos’ PH bandwidth. This interaction oscillates the neutrinos ability to maintain a constant information accumulation as mass. This buffeting is observable as oscillations in the neutrinos already miniscule energy and mass. A mass that may otherwise capture free debytons. Metaphorically, as a falling sky divers’ partially opened parachute is buffeted by the wind, the neutrinos’ information states known as flavors occur as its diminutive mass is buffeted by its interaction with free debytonic (dark) matter particles. While the neutrino interacts only minimally with the baryons and the leptons, the neutrino interacts more readily with the debytons as both bear a closer kinship via their more similar placement on the QE spectrum. While being buffeted on its relentless transitions through space, the neutrino’s attenuated information is teleported into the metaverse via the incident free debyton particles own hyper-dilated PH regimes. These are the same free debytonic PH regimes that when sequestered in normal matter would produce normal Einsteinian gravitation (G). This is also the same mechanism the LINE hypothesis proposes erodes dark holes in the early universe.
The attenuation of the neutrinos information content is quantized hence each debyton-neutrino interaction attenuates a proportional quantity of neutrino energy and mass to produce the observed neutrino oscillations as neutrinos travel through space. This suggests that neutrino oscillation may increase or decrease in the presence of local elevated or diminished debyton population in space. A gravityscape of free debytons too diminutive to produce measurable local gravitational influences will nonetheless manifest within neutrinos a quantized but circumstantially arbitrary spectrum of neutrino energy oscillations as neutrinos travel through regions of space having gradients in debytonic population. This infers that neutrinos don’t only oscillate between a few flavors, but define a quantized region on the universal QE spectrum.
By the universal information budget, as described by general relativity, a neutrinos extremely low mass defines a velocity very near to the maximum universal rendering rate, the speed of light. This near luminal velocity provides the neutrino with a perpetual supply of new information which perpetually replenishes the neutrinos loss of information due to its interaction with free debytonic particles. However, in the absence of free debytonic particles, neutrinos would not shed mass to oscillate, but instead would grow in mass into a more massive particle. A new neutrino perhaps, able to sequester a proportional quantity of debytonic (dark) matter particles and its accompanying gravitation. This new flavor of the venerable neutrino is called the dark neutrino and can only exist naturally within the debytonic deserts known as; voids.
In the year 1930 A.D. Wolfgang Pauli predicted the existence of an ephemeral undiscovered particle hypothesized to be carrying away missing energy from decaying radioactive nuclei. This particle was eventually detected by Reines and Cowan in 1956 and dubbed by Enrico Fermi the neutrino. The LINE hypothesis proposes that like all particles, the neutrino is a distinct type of particle and is also derivative of other particle types be they known or unknown. The neutrino is an intermediate particulate Planck Hole (PH) regime between the debytons (dark matter) and leptons. Like a lepton such as the electron, the neutrino hosts a pyrine structure that can retain information as mass but with a greater native PH bandwidth than any lepton. Additionally, like the debytons, the neutrino hosts a QE channel to metamatter but with a lesser PH bandwidth than the debytons. Unlike baryonic and leptonic pyrine, the neutrino pyrine sequesters no debyton particles due to its diminutive information accumulation as mass and therefor has undetectable charge. Some minimum amount of mass is required to produce the information circulation dynamics called charge, the strong force, and to sequester a proportional quantity of debytonic particles to produce the accompanying Einsteinian gravitation (G). This places the neutrinos’ information teleportation bandwidth natively higher by convention on the QE spectrum than the leptons but lower than the debytons. This structure makes the neutrino the intermediate link between leptonic (normal) matter and debytonic (dark) matter.
As neutrinos transition through space, its mass oscillates by the neutrino pyrines’ interaction with free debytonic (dark) matter particles as both travel through space. The lower PH bandwidth of baryonic and leptonic pyrine within protons and neutrons and electrons accumulates more information as mass due to their pyrine’s lower ground-state PH dilation. The ground-state PH dilation is the native PH bandwidth, with zero debyton particle sequestration within the central PH regime around which particulate pyrine form. Each debyton particle sequestered within the pyrines’ circulating information channel increases the QE bandwidth and gravitation of the pyrine and the particle it projects into the subatomic realm. Baryonic pyrine’s diminutive native drain of information into the metaverse accumulates more information within its pyrine, ergo; greater mass. This increased mass is able to sequester a normal quantity of free debytons to produce a normal Newtonian/Einsteinian gravitational potential (G). This increased baryonic information outflow called gravitation comes via the increased PH dilation of each additional sequestered debyton particles QE channel with metamatter. However, when there is insufficient mass accumulation around a ground-state particulate PH regime, a particle cannot accommodate the sequestration of a normal Einsteinian quantity of debytons within its pyrine structure. Consequently, free debytons that would normally become trapped within pyrine for a time or for an entire universal transition cycle, instead buffet and attenuate the ground-state PH bandwidth of vulnerable particulate PH regimes such as the neutrinos’ as both travel through space.
Each debyton-neutrino interaction causes a proportional attenuation of the neutrinos’ PH bandwidth. This interaction oscillates the neutrinos ability to maintain a constant information accumulation as mass. This buffeting is observable as oscillations in the neutrinos already miniscule energy and mass. A mass that may otherwise capture free debytons. Metaphorically, as a falling sky divers’ partially opened parachute is buffeted by the wind, the neutrinos’ information states known as flavors occur as its diminutive mass is buffeted by its interaction with free debytonic (dark) matter particles. While the neutrino interacts only minimally with the baryons and the leptons, the neutrino interacts more readily with the debytons as both bear a closer kinship via their more similar placement on the QE spectrum. While being buffeted on its relentless transitions through space, the neutrino’s attenuated information is teleported into the metaverse via the incident free debyton particles own hyper-dilated PH regimes. These are the same free debytonic PH regimes that when sequestered in normal matter would produce normal Einsteinian gravitation (G). This is also the same mechanism the LINE hypothesis proposes erodes dark holes in the early universe.
The attenuation of the neutrinos information content is quantized hence each debyton-neutrino interaction attenuates a proportional quantity of neutrino energy and mass to produce the observed neutrino oscillations as neutrinos travel through space. This suggests that neutrino oscillation may increase or decrease in the presence of local elevated or diminished debyton population in space. A gravityscape of free debytons too diminutive to produce measurable local gravitational influences will nonetheless manifest within neutrinos a quantized but circumstantially arbitrary spectrum of neutrino energy oscillations as neutrinos travel through regions of space having gradients in debytonic population. This infers that neutrinos don’t only oscillate between a few flavors, but define a quantized region on the universal QE spectrum.
By the universal information budget, as described by general relativity, a neutrinos extremely low mass defines a velocity very near to the maximum universal rendering rate, the speed of light. This near luminal velocity provides the neutrino with a perpetual supply of new information which perpetually replenishes the neutrinos loss of information due to its interaction with free debytonic particles. However, in the absence of free debytonic particles, neutrinos would not shed mass to oscillate, but instead would grow in mass into a more massive particle. A new neutrino perhaps, able to sequester a proportional quantity of debytonic (dark) matter particles and its accompanying gravitation. This new flavor of the venerable neutrino is called the dark neutrino and can only exist naturally within the debytonic deserts known as; voids.