Why You Should Read My Website [www.infiniteparticlephysics.com]
A
Provocative Question
Is Physics near the “end of the
line”, beyond which there is nothing to do, as various Nobel Laureates have
asserted? If this is so, why are the following prizes still unclaimed?
Unclaimed
Prizes in Physics
- For
discovering the space structure of gravity.
- For
discovering the space structure of charge.
- For
discovering the space structure of magnetism.
- For
discovering the space structures of photons, leptons, mesons, baryons and
nuclides.
- For
discovering the space structure of strong-force fields, and the reason for
their limited range.
- For
discovering the mechanics by which particles interact with fields
to incur accelerations.
- For
discovering the mechanisms of particle spins.
- For discovering
the mechanics of particle momentum.
- For
discovering the reason why mass-energy is conserved.
- For
discovering the origin and structure of matter-waves.
- For
discovering the interior structure of black holes and the space structure
of dark matter.
- For
discovering why photons and particles exhibit wave-particle duality.
- For
devising a simple scheme for calculating hadron mass-energies & bond
mass-deficits.
- For
discovering the geometrical aspects of nucleon bonding in nuclei.
- For
discovering the nuclide structural configurations leading to various decay
modalities.
- For
discovering the mechanics of electron capture by nuclei.
- For
showing how the whole of physics can be explained with just two
fundamental particles.
- For
showing how to visualize and thereby to explain quantum mysteries.
A Modest Answer
Physics is not at the “end of the
line”. Physicists have simply refused to consider the possibility that
particles may be infinite structures! All the above insights become evident
when one accepts that phenomena are actually infinitely extending
point-centered oscillatory distortion patterns in a bipolar particulate space
lattice. Here are some things that the study of my website will permit you to
do:
1) Learn New Concepts
& Techniques in Particle Physics
- Visualize the concepts
of mass, energy, and charge, and understand why mass-energy and charge
are conserved
- Visualize the process
by which energy transmogrifies into particles, e.g., understand how energy
produced by annihilations creates a slow-drifting spherical ECE packing-density
oscillation, which fractures the space lattice to create a defect cluster, and
then immediately splits into two oppositely-directed ellipsoidal oscillations.
In the process of splitting, each oscillator grabs half of the defect cluster,
and sequesters it at its center by a feedback process, this combination being
IPP’s concept of a particle (or antiparticle).
- Visualize in 3-D the
structure of any lepton or hadron particle listed in the LBL Review of
Particle Properties, e.g., perceive how muons differ from electrons, or how
muon neutrinos differ from electron neutrinos, or how the long mean-life form
of the neutral kaon differs from the short, or how the structure of a thermal
electron differs from that of a relativistic electron, or why there is
associated production of kaons in creating hyperons.
- Visualize in 3-D the
processes by which hadrons decay into lower mass hadrons, or into leptons
and/or energy.
- Calculate accurately
the mass of any hadron particle (often matching experimental values within ± 0.01%).
2) Learn New Concepts
& Techniques in Nuclear Physics
- Visualize the structural
differences between protons and neutrons, and thereby understand why a
neutron is heavier than a proton
- Visualize the geometrical
properties of the strong force, and thereby understand how nucleons self-organize into characteristic structures that are unique for each mix of x-protons
& y-neutrons, and how strong-force bonds are distributed amongst the nucleons comprising a nuclide cluster, and how to calculate
the mass-deficits of individual strong-force bonds in nuclides.
- Visualize nuclear destabilizing
agents and their mechanics, and thereby understand why nuclei decay
- Visualize the nuclear structural
anomalies that lead to various decay modalities, like beta + & beta −
decays, electron capture, or alpha, neutron, proton, & gamma
emissions, or fission, and thereby understand the rationale behind stable
and unstable nuclear isotopes
3) Learn New Concepts
& Techniques in Quantum Mechanics
- Visualize the
mechanics of wave-particle-duality, matter-waves, photons, polarization, spin,
& magnetism.
- Visualize the
mechanics of indeterminacy, electron tunneling, superconductivity,
superfluidity, relativistic mass increases, & the reason for annihilation
avoidance of orbiting electrons.
4) Learn New Concepts
& Techniques in Astrophysics
- Visualize
gravitational fields as gradients in the integrated packing density of
ECEs, and the effects of gravity as alterations in the ellipticity of a particle’s packing-density oscillation as it moves through radial
variations in these gradients.
- Perceive how redshift and microwave background radiation can be produced in a non-expanding
universe through photon ionization of void-pairs and their subsequent
recombinations, which evolves black-body radiation.
- Visualize black
holes as local change of the crystalline form of the space lattice from
distorted simple cubic to body-centered cubic.
- Visualize dark
matter as the gravitational effects of the grain-boundaries of
polycrystalline space.
- Get a clearer picture
of stellar processes like supernovae, etc., by being able to visualize the
space structures of protons, neutrons, electrons, and neutrinos, and by being
able to visualize the processes by which they convert into each other.
6) Keep Your Abstraction
Ladder On Solid Ground!
One of the very useful
contributions of General Semantics is the concept of the abstraction ladder,
a tool for clarity of thinking. This intellectual tool helps you avoid being
bamboozled by vague generalizations, by stepping backwards through the process
of generalization until you arrived at something concrete and verifiable. By
this down-stepping process, you can ascertain whether or not the proposal being
advocated has any grounding in reality. So, one keeps his thoughts cogent by
constantly climbing down abstraction ladders!
The problem that physicists
have with ladder descending is, of course, that physics depends on the ability
to integrate verifiable facts into generalizations, and generalizations into
laws. This requires climbing up the abstraction ladder, a
process fraught with intellectual hazards, unless one makes certain that the
ladder always rests on solid ground! Infinite Particle Physics gives you the
tools to do this, since all its concepts, no matter how complex, can be traced
back, ultimately, to interactions between point-centered infinite-extending
dynamic distortion patterns in the bipolar lattice of polycrystalline space.
