A Speculative Guide to Our Quantum Reality
(And a Very Speculative Proposal:
Quantum Antigravity)
A Speculative Guide to Our Quantum Reality
(And a Very Speculative Proposal:
Quantum Antigravity)
Pre-ambling
The Vacuum
Light
Particles
Dark Energy
Dark Matter
Black Holes
Checking the Map
Beyond the Forest
All in an Instant
No Ripples in Time
Alone in the Forest
References
Addendum: Cosmological constant problem
Addendum: Dark Matter Absorption Spectra
Addendum (a very speculative one)
Addendum What happened to the multiverse?
Addendum: On the Pauli Exclusion Principle
Addendum: A Model for the Neutron (and a proposal for a more exotic particle)
Addendum: The Lepton Family
Addendum: Neutrino Oscillation
Addendum: Duality in Time
Addendum: Wave-particle duality
Addendum: The Electron Orbital
Addendum: Electron-Positron Pair Production
Addendum: The Proton-Proton Chain
Addendum: The Structure of the Proton
Addendum: Quark Formation
Addendum: The Weak Nuclear Force
Addendum: Nuclear Structure From Deuteron Pairing
· Deuteron (H-2), alpha particle (He-4), Helion (He-3)
· Lithium-6 (Li-6), Triton (H-3), Lithium-7 (Li-7)
· Helium-5 (He-5), Beryllium-9 (Be-9), Beryllium-10 (Be-10)
· Boron-10 (B-10), Boron-11 (B-11)
· Carbon-12 (C-12), Carbon-13 (C-13), Carbon-14 (C-14)
· Nitrogen-14 (N-14)
· Oxygen-16 (O-16)
Addendum: Excited Nuclear Energy Levels
Addendum: Neutron Half-life Discrepancy
Addendum: Particle and Dark Matter Bremsstrahlung
Addendum: Antigravity from Deuteron Oscillation
Addendum: Proton magnetic resonance
A design proposal for an Interstellar Drive
Addendum: Electron and Neutrino Structure
Addendum: Structure of Dark Matter
Addendum: Why more matter than anti-matter?
The Universe as a Perpetual Quantum Motion Machine
Speculation on the Continuum
Entropy: The Fate of the Quantum Forest
Postscript: The Last ‘Tick’
Trail Blazing the Quantum Forest
Cosmological constant problem
Cosmological constant from Vacuum energy
Zero-point energy from particle projection
50 to 120 orders of magnitude discrepancy
Dark Energy drives Vacuum Network expansion
Particle projection localizes energy in VN
Large differential in diffuse vs localized energy
Dark Matter spectra from resonant graviton absorption
Dark Matter accretion on Black Hole horizon
Positive feedback drives supermassive Black Hole growth
Dark Matter graviton resonance
Ringdown from Black Hole merger
Wide graviton frequency spectrum
Dark Matter selective absorption
LIGO might detect absorption in graviton spectra
Quantum antigravity from momentary charge to entanglement conversion
Local spacetime and VN boundary entanglement
Global entanglement clock rate
Pulsed charge and momentary entanglement
Local entanglement increases as VN boundary entanglement decreases
Momentary reduction in projected static mass, no change in charge
Pulsed charge synchrony
Multiverse as an orthogonal spacetime
Spacetimes from local entanglement (AdS/CFT correspondence)
Local wavefunction propagation
Wavefunction “collapse” as local re-entanglement
Quantum foam mediates “spooky” action at a distance
Parallel universes as orthogonal spacetimes
One global VN with localized orthogonal spacetimes
Momentary energy isolation, no energy transfer
Conservation of energy prohibits energy transfer between spacetimes
Pauli Exclusion Principle
Two spin quantum numbers for orbital electrons
Different spins for electrons in same orbital
Photon circulation in electron’s antineutrino gravitational well
Photon circulation determines Intrinsic angular momentum
Spin up and down from photon polarizations
Synchronous particle projection in VN
No energy transfer between electron and proton projections
No overlap in magnetic fields from electrons in same orbital
Neutron has magnetic moment but no charge
Neutron decays to proton, electron and antineutrino
Charge isolation in antineutrino local spacetime
All spacetimes transparent to Quantum Foam
Neutron quark structure as proton with localized electron projection
Proton up quark ‘flipped’ to down by electron projection
Internal charge propagation drives neutron magnetic field
Exotic particle from deuterium and high energy antineutrinos
Neutron star may generate such exotic particles
Neutron star provides neutrinos and gravitons to source Dark Matter
Dark Matter not confined to neutron star surface
Enhanced Dark Matter halos in galaxies with high occurrence of neutron stars
Lab requirements for generation of Dark Matter particles
Lepton family: electron, muon, and tauon
High tauon mass requires entanglement energy of hadrons bound by strong force
Muon leptonic decay to electron, photon, electron antineutrino and muon neutrino
Tauon hadronic decay to two pions and a tau neutrino
Charged pion decay to muon and muon neutrino
Neutral pion an unstable meson, transitions to gamma photon
Muon heavier and larger magnetic moment than electron
Muon formed by electron and antineutrino projecting into electron neutrino spacetime
Muon mass from component masses
Muon magnetic field from electron and altered photon circulation on antineutrino
Tauon mass from projection of heavy neutrinos forming quark pairs (pions)
Tau neutrino isolates charged pion from VN
Positive charge of pion decays to negative muon
Photon phase shift on less dense muon flips pion charge to negative
Neutral pion decay to gamma photon suggests direct neutrino conversion
Neutrino oscillates in the VN between three flavours, all of low mass
Near light speed transmission causes entanglement transients in VN
No net energy transfer occurs, but local transients can be isolated from VN
Transients alter neutrino geometry
Flavour oscillation is oscillation in local geometry
Entanglement transients can be restored to VN with no net energy transfer
Strong gravitational fields in VN may enhance flavour oscillation
Duality in Time
Holographic Duality in the Quantum Forest
AdS/CFT correspondence
Holographic principle
Converse describes our spacetime
Extending the Holographic principle to particles
Wave-particle duality as Holographic Duality
Duality is structure
Electron orbital dynamics
Electron spherical projection
Hydrogen ground state
1-s orbital
Photon absorption
2-s orbital
Photon node formation
Node surface area affects orbital stability
Photon polarization
Pauli Exclusion Principle from photon polarity
Electron-positron pair production
Neutrino chirality
Stellar pair production
Proton-proton chain
Stellar ignition requirements
Entanglement requirement
Gravitational neutrino production
Moving charge requirement
Magnetic field from moving charge
Photon formation in chiral spacetimes
Stellar deuteron production
Fusion reaction requirements
Entanglement from focused shock waves
Deuteron oscillation rate
Proton structure
Quarks entangled as single spacetime
Photon circulation and quark charge
Up vs down quark mass difference
Photon phase shift from internal reflection
Strong force as gravitational entanglement
Quark formation as charge conservation
Boundary entanglement enhancement
Quarks from proton ‘proto’ particle
Weak nuclear force
Antineutrino shields charge in neutron spacetime
Electron magnetic flux from deuteron oscillation
Magnetic attraction vs Coulomb repulsion
Deuteron internal momentum transfer
Deuteron dynamical symmetry
Proton-neutron oscillation as Weak force
Nuclear structure
Proton-neutron oscillation
Deuteron electric quadrupole moment
Deuteron pairing
Deuteron (H-2), alpha particle (He-4), Helion (He-3)
Lithium-6 (Li-6), Triton (H-3), Lithium-7 (Li-7)
Helium-5 (He-5), Beryllium-9 (Be-9), Beryllium-10 (Be-10)
Boron-10 (B-10), Boron-11 (B-11)
Carbon-12 (C-12), Carbon-13 (C-13), Carbon-14 (C-14)
Nitrogen-14 (N-14)
Oxygen-16 (O-16)
Low energy nuclear interactions
Deep inelastic scattering
Weak nuclear binding force
Up Quark electron orbital
Nuclear current flow
Entanglement clock rate (> sextillion Hz)
Scattering radius
Charge radius
Inter-nucleon separation
Dynamical symmetry
Nuclear instability
Moment of inertia
Magnetic moment flipping
Free vs paired proton
Anisotropy in scattering radius
Beta decay
Tritium half-life
Free neutron stabilization
He-5 half-life
Hybrid neutron bonding
Barbell geometry
Alpha clusters
Triton bridge
Nuclear shell model
Quark photon nodes
Mossbauer effect
Gamma transitions
Magnetic field projection between spacetimes
Masked charge projection
Electron acceleration
Particle Bremsstrahlung
No infinite self-energy, ultraviolet cut-offs, or renormalization
Neutrino entanglement energy
Electron state change
Electron photon absorption
Electron braking Bremsstrahlung
Dark Matter acceleration
Dark Matter Bremsstrahlung
Dark Matter graviton absorption
Dark Matter inverse Bremsstrahlung
Black Hole graviton absorption by Dark Matter
Enhanced galactic spin rates by Dark Matter Bremsstrahlung
Neutron half-life discrepancy
Magnetic bottle
Magnetic flux effects on neutron stabilization
Antigravity from deuteron oscillation
Deuteron oscillation at global clock rate
Momentary entanglement and conservation of energy
Momentary entanglement reduction in VN
Momentary transfer to local spacetimes
Entanglement strobing in the VN
Deuteron source for timing pulses
Deuterium crystal in strong magnetic field
Shock wave heterodyning
Contrast with cluster fusion
Proton magnetic resonance
Interstellar travel
Reaction Mass Limitation
Holographic principle applied to particles
Proton destabilization
Interstellar drive design requirements
Electron, neutrino, Dark Matter internal structure
Anti-matter abundance
Perpetual quantum motion machine
Intrinsic spin flipping
Boundary entanglement
Transverse electric mode
Transverse magnetic mode
Global projection operator
Orthogonal Hilbert space
Gyromagnetic ratio
Dirac electron
Dirac spinor
Negative mass
Kerr Black Hole
Antineutrino spin
Mach Principle
Antineutrino network (AN spacetime)
Null Geodesics (prograde, retrograde)
Vacuum Network rotation
Graviton longitudinal wave
Dark Matter spin
Gyro-entanglement ratio
Electron-positron pair creation
Spacetime chirality
Continuum phase space
Anti-universe
Measure zero domain
Quantum chaos
Von Neumann entropy
Quantum Entropy in discrete time
Dark Energy Entropy
Black Hole Entropy
Essential singularity
Entanglement heat engine
Existential differential
Final foliation
Universe as a simulation
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