The Evolution of Time (Director's Cut)
Δημοσιεύτηκε στις 3 Φεβ 2014
The Evolution of Time and the Carnot Cycle at the Edge of the Universe
By Gavin Wince
We
are all time travelers... drifting through time at a steady pace, one
moment at a time. In what direction are we moving through time? Or does
time move through us? How many dimensions of time are there? Though
slightly allegorical, three-dimensional time offers physics new
parameters, accounting for conventional and exotic physical phenomena,
while maintaining the conservation of energy and symmetry groups found
in physical law.
I began playing with the idea that all of
physics could be reduced to just interactions between spatial and
temporal coordinates. I wondered if inertia and momentum might be
composed strictly of temporal components. This would require extra time
dimensions. Could inertia or momentum be used as indicators of
multi-dimensional time? What about charge, spin, and other properties of
matter? Answers to some of these questions appeared to reside in
neutrino research, specifically neutrino flavor oscillation.
The
universality between Thermodynamics and Temporal Mechanics can reduce
the fundamental forces of nature into a single expression, a new
equivalence principle, which can be used as the generator for the
evolution of time.
Once Quantum Mechanics is seen through the
lens of three-dimensional time, the EPR paradox looses its mystique. The
speed of light may be restricted to a set speed limit within each
individual frame of reference, however, frames of reference can undergo
periods-of-time at varying rates of the passage-of-time.
If the
positive side of absolute zero is a state of condensed matter, what is
on the negative side of absolute zero? Uncondensed matter?
The
anti-matter aspect of the Dirac equations may have been misinterpreted.
The convention is to assume that "matter" is composed of "particles"
distinctly different from "antimatter" composed of "antiparticles". The
assumption of one time dimension locks in this interpretation of the
Dirac Equations. However, the uniform production of particles and
antiparticles both in the laboratory and naturally, leads to the
question: where is all of the antimatter that theoretically should have
been produced with all the visible matter we see as our universe? Yet,
if we apply our three-dimensional time loop to the Dirac Equation there
is an alternative interpretation for this so-called "missing
antimatter".
The Higgs particle data from both ATLAS and CMS
appear to exhibit unintentional effects of quantum entanglement.
Comparing the neutral Kaon mixing CP-violation and the neutral B-meson
oscillation T-violation with the Higgs particle decay modes appear to
demonstrate a new kind of symmetry breaking: M-Violation (mass).
With
out a begin or an end, from the smallest to the largest, the universe
emerges through upwelling from the infinitesimal depths of quantum
fluctuations and cataclysmic eruptions amalgamating through a variety of
entropic cycles of temporal loops.
By Gavin Wince
We
are all time travelers... drifting through time at a steady pace, one
moment at a time. In what direction are we moving through time? Or does
time move through us? How many dimensions of time are there? Though
slightly allegorical, three-dimensional time offers physics new
parameters, accounting for conventional and exotic physical phenomena,
while maintaining the conservation of energy and symmetry groups found
in physical law.
I began playing with the idea that all of
physics could be reduced to just interactions between spatial and
temporal coordinates. I wondered if inertia and momentum might be
composed strictly of temporal components. This would require extra time
dimensions. Could inertia or momentum be used as indicators of
multi-dimensional time? What about charge, spin, and other properties of
matter? Answers to some of these questions appeared to reside in
neutrino research, specifically neutrino flavor oscillation.
The
universality between Thermodynamics and Temporal Mechanics can reduce
the fundamental forces of nature into a single expression, a new
equivalence principle, which can be used as the generator for the
evolution of time.
Once Quantum Mechanics is seen through the
lens of three-dimensional time, the EPR paradox looses its mystique. The
speed of light may be restricted to a set speed limit within each
individual frame of reference, however, frames of reference can undergo
periods-of-time at varying rates of the passage-of-time.
If the
positive side of absolute zero is a state of condensed matter, what is
on the negative side of absolute zero? Uncondensed matter?
The
anti-matter aspect of the Dirac equations may have been misinterpreted.
The convention is to assume that "matter" is composed of "particles"
distinctly different from "antimatter" composed of "antiparticles". The
assumption of one time dimension locks in this interpretation of the
Dirac Equations. However, the uniform production of particles and
antiparticles both in the laboratory and naturally, leads to the
question: where is all of the antimatter that theoretically should have
been produced with all the visible matter we see as our universe? Yet,
if we apply our three-dimensional time loop to the Dirac Equation there
is an alternative interpretation for this so-called "missing
antimatter".
The Higgs particle data from both ATLAS and CMS
appear to exhibit unintentional effects of quantum entanglement.
Comparing the neutral Kaon mixing CP-violation and the neutral B-meson
oscillation T-violation with the Higgs particle decay modes appear to
demonstrate a new kind of symmetry breaking: M-Violation (mass).
With
out a begin or an end, from the smallest to the largest, the universe
emerges through upwelling from the infinitesimal depths of quantum
fluctuations and cataclysmic eruptions amalgamating through a variety of
entropic cycles of temporal loops.
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