EFT: The Universe Truth Manual
A worldview radically different from today’s physics.
AI‑readable knowledge base: a full, on‑the‑spot showdown with 【the full mainstream physics stack】.
Comprehensive Evaluation Report
Chapter 1: Base Map for a New Worldview | Energy Filament Theory (EFT V6.0)
- 1.0 One-Page Overview: Version Roles, the Four-Layer Map, and How to Use It
- 1.1 Five Minutes Before the Breakthrough: Which Intuitions Must We Unlearn?
- 1.2 Axiom One: The Vacuum Is Not Empty—The Universe Is a Continuous Energy Sea
- 1.3 Axiom Two: Particles Are Not Points—Locked Loop Structures Formed in an Energy Ocean
- 1.4 Sea-State Quartet: Density, Tension, Texture, and Cadence
- 1.5 Relay: A Unified Language for Propagation, Information, and Energy
- 1.6 Field: Not an Object, but the Sea’s Weather and Navigation Map
- 1.7 How Particles "See" a Field: Different Channels, Not Being Pulled, But Finding a Path
- 1.8: Force: Gradient Settlement (F=ma and the "Tension Ledger" of Inertia)
- 1.9. Boundary Materials Science: Tension Walls, Pores, and Corridors
- 1.10 The Speed of Light and Time: The Real Upper Limit Comes from the Sea; the Measured Constant Comes from Rulers and Clocks
- 1.11 Particle-Structure Lineage: Stable and Short-Lived Particles and Where Generalized Unstable Particles Fit
- 1.12 Where Particle Properties Come From: A Structure–Sea State–Property Map
- 1.13 The Structure and Properties of Light: Wave Packets, Twisted Light Filaments, Polarization, and Identity
- 1.14 Light and Particles Share One Root; Wave Behavior Has One Source
- 1.15 Redshift Mechanism: Tension Potential Redshift Sets the Baseline, Path Evolution Redshift Adds Fine Tuning
- 1.16 Dark Pedestal: The Two-Sided Effect of Short-Lived Filaments (Generalized Unstable Particle, Statistical Tension Gravity, Tension Background Noise)
- 1.17 Gravity and Electromagnetism: The Tension Slope and the Texture Slope (Two Maps)
- 1.18 Swirl Textures and Nuclear Force: Alignment and Locking
- 1.19 Strong and Weak Forces: Structural Rules and Transformation, Not an Extra Pair of Hands
- 1.20 Unifying the Four Forces: Three Mechanisms + Rule Layer + Statistical Layer (Master Table)
- 1.21 Structure Formation Blueprint: Texture → Filament → Structure (Minimum Building Block)
- 1.22 Microstructure Formation: Linear Texture + Spiral Texture + Cadence → Orbitals, Interlocking, Molecules
- 1.23 Macro-Scale Structure Formation: Black Hole Spin Vortices Shape Galaxies; Linear Striation Docking Builds the Cosmic Web
- 1.24 Participatory Observation: Measurement Systems, a Shared Origin for Rulers and Clocks, and Cross-Epoch Comparison
- 1.25 Extreme Cosmic Scenarios: Black Holes, Boundaries, and Silent Cavities
- 1.26 The Early Universe: Reality’s Factory Settings
- 1.27 Cosmic Evolution as Relaxation: The Baseline Tension Timeline
- 1.28 The Modern Universe: A Zoning Map, a Structural Map, and an Observation Playbook
- 1.29 A Unified Picture of Cosmic Origin and End-State
- 1.30 Physical Upgrade Map: How Energy Filament Theory Relates to Existing Physics, a Test Checklist, and an Artificial Intelligence Index
Chapter 1: Energy Filament Theory (V5.05)
- 1.1 Prologue
- 1.2 Ontology: Energy Threads
- 1.3 Background: The Energy Sea
- 1.4A Property: Density
- 1.4B Property: Tension
- 1.4C Property: Texture
- 1.5 Tension Sets the Speed of Light
- 1.6 Tension Sets the Pull
- 1.7 Tension Sets the Tempo (TPR,PER)
- 1.8 Tension Sets Coordination
- 1.9 Tension Wall (TWall) and Tension Corridor Waveguide (TCW)
- 1.10 Generalized Unstable Particles (GUP)
- 1.11 Statistical Tension Gravity (STG)
- 1.12 Tension Background Noise (TBN)
- 1.13 Stable Particles
- 1.14 Tensional Origins of Particle Properties
- 1.15 Four Fundamental Forces
- 1.16 Disturbance Wavepackets: Unifying Radiation and Directionality
- 1.17 Unity: What EFT Unifies
Chapter 2: Consistency Evidence (V5.05)
- 2.0 Reader’s Guide
- 2.1 Core Evidence for Consistency of the Sea-and-Threads Picture
- 2.2 Cross-Disciplinary Support and Cosmic-Scale Cross-Checks for the Sea-and-Threads Picture
- 2.3 Consistency Evidence for Merging Galaxy Clusters
- 2.4 The Energy Sea Is Elastic: Consistency Evidence for Its Tension Properties
- 2.5 An Integrated Synthesis of the Consistency Evidence Chain
Chapter 3: Macroscopic Universe (V5.05)
- 3.1 Galaxy Rotation Curves: Fitting Without Dark Matter
- 3.2 The “Excess” Cosmic Radio Background: Raising the Floor Without Hidden Point Sources
- 3.3 Gravitational Lensing: A Natural Outcome of the Tensional Potential
- 3.4 Cosmic Cold Spot: The Fingerprint of Path Evolution Redshift
- 3.5 Cosmic Expansion and Redshift: A Tension-Reconstruction View of the Energy Sea
- 3.6 Nearby Redshift Mismatch: A Source-Side Tension Model
- 3.7 Redshift-Space Distortions: Line-of-Sight Velocity Effects Organized by the Tensional Field
- 3.8 Early Black Holes and Quasars: Energy-Thread Collapse in High-Density Nodes
- 3.9 Quasar Polarization Alignments: A Far-Field Orientation Fingerprint of Tensional-Structure Synergy
- 3.10 Cosmic High-Energy Emissaries: A Unified Picture of Tension Channels and Reconnection Acceleration
- 3.11 The Lithium-7 Puzzle in Primordial Nucleosynthesis: Dual Corrections via Tension Rescaling and Background-Noise Injection
- 3.12 Where Did Antimatter Go: Non-Equilibrium Freeze-Out and Tensor Bias
- 3.13 Cosmic Microwave Background: From a Noise-Blackened Plate to Path and Terrain Fine Patterns
- 3.14 Horizon Consistency Without Inflation: Far-Field Isothermality with Variable Light Speed
- 3.15 How Cosmic Structure Grows: Filaments and Walls Through the Lens of Surface Tension
- 3.16 The Universe’s Beginning: Global Locking Without Time and a Phase-Change Release
- 3.17 The Universe’s Future: Long-Term Evolution of the Tension Terrain
- 3.18 Aether Theory: From a Disproved “Static Sea” to an Evolving “Energy Sea”
- 3.19 Gravitational Deflection vs. Material Refraction — Where Background Geometry Ends and Material Response Begins
- 3.20 Why Straight, Collimated Jets Appear: Applications of the Tension Corridor Waveguide (TCW)
- 3.21 Cluster Mergers (Galaxy Collisions)
Chapter 4: Black Holes (V5.05)
- 4.1 What a Black Hole Is: What We Observe, How We Classify It, and Why Explaining It Is Hard
- 4.2 Outer Critical: One-Way Speed Threshold
- 4.3 Inner Critical Band: Watershed Between the Particle Phase and the Filament-Sea Phase
- 4.4 The Inner Core: The Hierarchy of a High-Density Filament Sea
- 4.5 The Transition Zone: The “Piston Layer” Between the Outer Critical and the Inner Critical Band
- 4.6 How the Cortex Appears and Speaks: Rings, Polarization, and Common Timing
- 4.7 How Energy Gets Out: Pores, Axial Perforation, and Edgewise Band-Like Subcriticality
- 4.8 Scale Effects: Small Black Holes Are “Fast,” Large Black Holes Are “Steady”
- 4.9 Crosswalk With Modern Geometric Narratives: Agreements and Added Material Layers
- 4.10 Evidence Engineering: How to Test, What Fingerprints to Watch, and What We Predict
- 4.11 Black Hole Fates: Phases, Thresholds, and Endgames
- 4.12 Fourteen Questions People Ask About Black Holes
Chapter 5: Microscopic Particles (V5.05)
- 5.1 Origins: Particles as Miracles Amid Countless Failures
- 5.2 Particles Are Not Points but Structures
- 5.3 The Nature of Mass, Charge, and Spin
- 5.4 Forces and Fields
- 5.5 The Electron
- 5.6 Proton: A Weave-of-Rings Diagram and Reading Guide
- 5.7 Neutron: Ring-Weave Picture, Intuition Aids, and Checks
- 5.8 Neutrino: Ring-Phase Minimal Weave—Visualization, Intuition, and Checks
- 5.9 The Quark Family
- 5.10 The Atomic Nucleus
- 5.11 Atlas of Nuclear Structures by Element
- 5.12 Atoms (Discrete Energy Levels, Transitions, and Statistical Constraints)
- 5.13 Wave Packets (Bosons, Gravitational Waves)
- 5.14 Predicted Particles
- 5.15 Mass–Energy Conversion
- 5.16 Time
Chapter 6: Quantum Domain (V5.05)
- 6.1 Photoelectric Effect and Compton Scattering
- 6.2 Spontaneous Emission and Where Light Comes From
- 6.3 Wave–Particle Duality
- 6.4 Measurement Effects
- 6.5 Heisenberg Uncertainty and Quantum Randomness
- 6.6 Quantum Tunneling
- 6.7 Decoherence
- 6.8 Quantum Zeno and Anti-Zeno Effects
- 6.9 The Casimir Effect
- 6.10 Bose–Einstein Condensation and Superfluidity
- 6.11 Superconductivity and the Josephson Effect
- 6.12 Quantum Entanglement
Chapter 8: Paradigm Theories Challenged by Energy Filament Theory (V5.05)
- 8.0 Foreword — How Energy Filament Theory Recasts “Paradigms”
- 8.1 The Strong Version of the Cosmological Principle
- 8.2 Big Bang Cosmology: Restating a Single-Origin Story—And Testing It
- 8.3 Cosmic Inflation
- 8.4 Redshift Is Not Uniquely Explained by Metric Expansion
- 8.5 Dark Energy and the Cosmological Constant
- 8.6 Standard Origin of the Cosmic Microwave Background
- 8.7 The “Unique Fingerprint” Status of Big Bang Nucleosynthesis
- 8.8 The ΛCDM “Standard Cosmology”
- 8.9 The Only Picture Where Gravity Equals Curved Spacetime
- 8.10 Status of the Equivalence Principle as a Postulate
- 8.11 Strong Form: Global Causality Determined Entirely by the Metric Light Cone
- 8.12 Universality of the Energy Conditions
- 8.13 Absolute Horizon and the Information Paradox Framework
- 8.14 Dark-Matter Particle Paradigm
- 8.15 The “Absoluteness of Natural Constants” Paradigm
- 8.16 The Postulate of Photon Absoluteness
- 8.17 Symmetry Paradigm
- 8.18 The Roots of Bosonic and Fermionic Statistics
- 8.19 Four Fundamental Interactions Are Independent
- 8.20 Mass Arises from Higgs Assignment—EFT Reinterpretation
- 8.21 Quantum Theory: Ontology and Interpretation
- 8.22 Statistical Mechanics and Thermodynamics: Paradigm Assumptions
Appendix-1. Prediction and Falsification (V6.0)
- 1. Path-Level Achromatic Common Term: Cross-Probe Corroboration
- 2. Environment Feed-Forward Test of the Strong-Lens Time-Delay Potential Term
- 3. Source-Side Calibration Using Multi-Line Common Shifts and Invariant Ratios
- 4. Rotation Curves and Weak Lensing Closure: Smooth Dark Pedestal and Tension Slope Without Per-Galaxy Halo Profiles
- 5. Radio Background Floor Test for the Absolute Radiometer for Cosmology, Astrophysics, and Diffuse Emission 2: Discrete-Source Superposition Limit and Anisotropy Suppression
- 6. Cosmic Microwave Background Mu and Y Spectral Distortions: Injection Windows, Templates, and a Lower-Bound Floor
- 7. Co-Located Scaling of Black Hole Near-Rings: Shared Time Lags and Polarization Flip Bands
- 8. Active Galactic Nucleus Jets: Axial Punch-Through and Alignment with the Cosmic Web Filament Skeleton
- 9. A Smooth Statistical Field Explanation for Strong-Lens Flux Ratios and Central-Image Rates
- 10. Intermittent-Channel Fingerprints in Quantum Tunneling: Heavy-Tailed Waiting Times, the Fano Factor, and Zero-Lag Co-Occurrence
- 11. Dynamic Casimir Thresholds and Post-Threshold Nonlinearity: From Wall Speed to Yield and Spectral Switching
- 12. Engineerable Vacuum in Cavity Quantum Electrodynamics: Coupled Emission–Absorption and Common-Term Closure
- 13. Decomposing Nearby Redshift Mismatches into Endpoint and Path Terms
- 14. Path Redshift Evidence Along the Cosmic Microwave Background Cold Spot Sightline
- 15. Quasar Polarization Group Alignment and Cosmic-Web Orientation Synergy
- 16. Coexisting High Fueling and Slow Leakage in High-Redshift, High-Mass Black Holes
- 17. Alignment Between Satellite Co-rotation Planes and the Host Filament Axis
- 18. Large Hadron Collider Jet In-Channel Coherence Under Event Congestion: Particle-Level Proxies for Spiral and Texture Channels
- 19. In-Situ Imaging of Tension-Wall Breathing in Josephson Junctions
- 20. Solar-Conjunction Same-Source Multipath Common Term Across Solar-System Links
- 21. Saddle-Point Image Ablation Excess in Strong Gravitational Lensing
- 22. Jet-Core Brightness–Polarization Co-Variation at the Same Location and Time Window (Zero-Lag Index and Faraday De-Rotation Robustness)
- 23. Four-Dimensional Tomography of a Common Component in 21 Centimeter Intensity Mapping (Pixel–Redshift–Environment–Common Component)
- 24. Differential Propagation Test Across Environmental Corridors Under a Single External Timebase (Common-Component Upper Bound)
- 25. Steady-State Crossing of the Schwinger Limit in the Laboratory and No-Medium Dependence
- 26. Dynamic Near-Horizon Stratification as a Dual Structure of Fault Bands and Pore Channels: Ring-Width Breathing and Azimuthal Phase Locking
- 27. Four-Dimensional Tomography of Cosmic-Scale Path Redshift: Sky Region, Redshift, Environment, and a Common Component
- 28. Environmental Decoherence Limits for Ultra-Long-Baseline Entanglement
- 29. Precision CMB Spectral-Distortion “Injection History” and Persistent Noise-Floor Tests
- 30. Full-Parameter Phase Diagram for a Vacuum “Tension-Wall” Analog Platform
- 31. Direct Evidence for Early-Universe “De-Inflation” Horizon Consistency
- 32. Multi‑Probe Closure for a Panoramic Map of Orientation Coherence: A Reproducible Latent Direction‑Field Product
- 33. A Non‑Dispersive “Image–Image” Common‑Component Sequence in Strongly Lensed FRBs
- 34. Dispersion‑Free Image‑to‑Image Common‑Mode Residuals in Strongly Lensed Gravitational Waves
- 35. Testing Potential‑Scaled Common Drift in a Global Atomic‑Clock Height Network
- 36. Zero-Dispersion Common Delay in Ultra-Long Fiber Links and Its Link to Crustal Tension
- 37. A Smooth Baseline Residual Test for Galaxy-Cluster Thermal and Kinematic Sunyaev–Zel’dovich Signals
- 38. Nuclear Outflow Slow-Leak Spectra Co-Located with Pore Breathing
- 39. A Dual-Frequency Solar-Grazing Planetary Radar Common-Term Profile
- 40. Environment-Predictable Residuals in Time-Delay Cosmology
- 41. Common-Term Isolation in a Lunar Occultation Test Using Curvature-Tunable Beamforming Antennas
- 42. Common-Term Consistency in a Gravitational Microlensing Time-Series Mosaic
- 43. Cross-Type Star Comparison of a Smooth Baseline Noise in Asteroseismic Bands
- 44. Day–Night Difference Test for Multi-Frequency Link Path Redshift in Near-Earth Spacecraft
- 45. Neutrino Arrival-Time Structure and a Cross-Baseline Non-Dispersive Common Term
- 46. Evidence for Tension Resonance in Coupled Earthquake, Gravity, and Long-Haul Optical Fiber Data
- 47. Environmental Dependence of Polarization Rotation in Gamma-Ray Burst Afterglows
- 48. Search for a Common Term in Exoplanet Transit and Secondary Eclipse Timing Residuals
- 49. Slow-Leak Signature in Comet-Tail Plasma After Solar Wind Removal
- 50. Seasonal Drift of a Non-Dispersive Smooth Term in Pulsar Timing Arrays
- 51. Joint Signature of a Diverging Lens and a Tension-Wall Shell in Static Holes
- 52. Galaxy Cluster Mergers: Four-Phenomena Coupling and a “Noise-Then-Force” Timeline in Statistical Tension Gravity and Tension-Born Local Noise
- 53. Merging Galaxy Clusters as a Calibration Field for Path-Equivalent Redshift and Non-Dispersive Common Terms: Rigid Multi-Probe Alignment
- 54. Fixed-Time-Constant Relaxation of the Convergence–X-Ray Offset: A Merger Memory Ruler
- 55. Spatial Covariance of Statistical Tension Gravity and Tension-Born Local Noise in Merging Galaxy Clusters: Co-Located, Co-Aligned κ Residuals and Non-Thermal Turbulence Readouts
- 56. Consistency Test for Chiral Scattering in the Proton Near Field Using Orbital Angular Momentum Probes
- 57. Proton Mid-Field Form Factor With an Enhanced Outer Rim: A Repeatable Radial Profile
- 58. Linear Micro-Drift of the Proton Magnetic Moment Under a Controlled Tension Gradient
- 59. Time-Domain Fingerprint of Proton Bound-Belt Reconnection: Short Echoes and Synchronous Spectral Flares
- 60. Cancellation Fingerprint in Neutron Near-Field Chiral Scattering with Orbital Angular Momentum: A Reversible Outer-Negative, Inner-Positive Pattern
- 61. Imaging the Neutron’s Negative Charge Radius: A Multi-Energy Consistency Test of Form Factors
- 62. Even-Function Response of the Neutron Magnetic Moment to a Tension Gradient: Suppressed Linear Term and Quadratic Scaling
- 63. Geometric Co-Features of Beta Minus Conversion: Proton-State Growth, Electron Wave-Packet Nucleation, and Electron Antineutrino Wave-Packet Timing Correlation
- 64. Mirror Geometric Co-Features of Beta-Plus Conversion: Neutron-State Growth, Positron Wave-Packet Nucleation, and Neutrino Wave-Packet Timing Correlation
- 65. Mirror-Sign Time Steps in the Nondispersive Common Term for Beta-Minus and Beta-Plus: An Arbitration Test Between Neutrinos and Antineutrinos
- 66. Two-Station Propagation Scaling of the Nondispersive Common-Term Step: Linear in Distance and Independent of Energy
- 67. Transverse Beam Footprint and Coherence Cone Angle of the Nondispersive Common-Term Step: Off-Axis Attenuation Scaling
- 68. Geometric On-Axis Amplitude Decay of the Dispersionless Common-Term Step (Constant H₀ × Distance and Conserved Transverse Flux)
- 69. One-Map Multi-Probe Consistency Test for the Relaxation-Evolution Principal Axis (Distance Residuals, Weak Lensing, and Strong-Lens Time Delays on a Shared Base Map)
- 70. Joint Fit Hard Constraint for Redshift Decomposition: Through-Path Residual Baseline and Punctuated Event Residual Micro-Adjustments, Dispersionless Across Carriers
- 71. Opposite-Sign Response Between Beat Rate and Propagation (Tight Regions Slow the Beat but Speed Up Transmission; Loose Regions Speed Up the Beat but Slow Transmission)
- 72. Cross-Era Drift Audit for Co-Origin Length and Time Standards (A Common Tension Trajectory Stays Continuous Through Second-Standard Transitions)
- 73. Unified Cross-Probe Metrics Table for the Dispersionless Common Term (Zero-Lag Index and Same-Window Closure)
- 74. Statistical Fingerprints of Rule-Level Threshold Discreteness and Chain Rewriting (Cross-Platform Coupling of Decay Chains and Threshold States)
- 75. Falsification Line for the Claim That a Field Is Only a Sea-State Map (Boundary Changes Drive Sea-State Changes, Then Joint Emission/Absorption Response)
- 76. Predictability Test for “Road Network First” Structure Formation (Skeleton Aligns First, Matter Fills Later)
Appendix-2. New Worldview|S01 script (V5.05)
- 1.1 Why Is Empty Space Full of Energy?
- 1.2 How Does the Universe Really Work Inside?
- 1.3 What Came Before Space and Time?
- 1.4 Why Might the Universe Not Need Dark Matter?
- 1.5 Why Does the Universe Grow a Cosmic Web?
- 1.6 What If Redshift Is Time Stretch, Not Flight?
- 1.7 What Shape Does the Electron Really Have?
- 1.8 Why Is Light Not a Little Flying Bullet?
- 1.9 What Are Forces Made Of in the Vacuum?
- 1.10 How Do Black Holes Quietly Rule the Cosmos?
Appendix-3. Microscopic Particles|S02 script (V5.2)
- 2.1 Why Aren’t Particles Just Tiny Points?
- 2.2 Why Do Ring Particles Survive Best?
- 2.3 How Do Cosmic Filaments Form in Space?
- 2.4 Could the Universe Work Without Dark Matter?
- 2.5 Why Was the Electron First to Be Stable?
- 2.6 Why Do Neutrinos Barely Interact at All?
- 2.7 What Really Gives Mass and Gravity?
- 2.8 What Is Electric Charge Actually Made Of?
- 2.9 Why Does Magnetism Exist in the First Place?
- 2.10 Why Do Particles Carry Tiny Spirals?
- 2.11 What Is Magnetic Moment Really Telling Us?
- 2.12 Why Do Magnets Pull Iron So Strongly?
- 2.13 Why Isn’t Spin Just Simple Rotation?
- 2.14 Why Does Phase Control Waves and Signals?
- 2.15 What Is the Weak Force Really Made Of?
- 2.16 Why Can’t a Single Quark Exist Alone?
- 2.17 How Do Three Quarks Lock into One Proton?
- 2.18 Why Do Neutrons Live but Still Decay?
- 2.19 Why Isn’t the Strong Force Just Glue?
- 2.20 How Do Nuclei Manage to Hold Together?
- 2.21 Why Doesn’t the Electron Just Fall Into the Nucleus?
- 2.22 Why Do Electrons Emit Light When Orbits Jump?
- 2.23 Can Particle Properties Really Change with Time?
- 2.25 Why Do Elements Have a Highest Possible Number?
- 2.26 How Do Atoms Know Who They Can Bond With?
- 2.27 What Is a Chemical Bond at Its Core?
- 2.28 Why Does Matter Stay Together for So Long?
- 2.29 Where Do Particle Properties Truly Come From?
- 2.31 Why Do Atomic Clocks Drift Over Time?
- 2.32 Why Are Different Particles Out of Sync?
- 2.33 Why Is the Proton Radius So Hard to Nail?
- 2.34 Why Don’t Neutron Lifetime Results Agree?
- 2.35 Why Does Positronium Die So Quickly?
- 2.36 Why Is Electron Magnetism a Bit Too Strong?
- 2.37 Why Are Cosmic Spectra Slightly Twisted Inside?
- 2.38 Why Do Some Distant Molecules Look Wrong?
- 2.39 Why Is the Universe’s Lithium So Low?
- 2.40 Why Do Cosmic Signal Frequencies Slowly Drift?
- 2.41 Why Do These Ten Clues All Point One Way?
- 2.42 How Are Light and Particles Deeply Connected?
Appendix-4. Light & Time|S03 script (V5.2)
- 3.1 How Does Light Cross Supposedly Empty Space?
- 3.2 Why Isn’t Light Really Flying Through Space?
- 3.3 Why Does Sunlight Make Your Skin Feel Hot?
- 3.4 How Can One Bulb Light a Whole Room?
- 3.5 Why Does Light Pick Certain Directions?
- 3.6 How Can Starlight Travel for Billions of Years?
- 3.7 Why Does Light Split into Different Colors?
- 3.8 What Is the Actual Shape of a Light Beam?
- 3.9 Why Don’t Colliding Beams of Light Interfere?
- 3.10 Why Can Glass Pass Light but Stay Dark?
- 3.11 Why Does Light Bend Near Heavy Objects?
- 3.12 How Can a Light Wave Turn Into Matter?
- 3.13 Why Doesn’t Light Leave Permanent Footprints?
- 3.14 Can Light Cross the Universe without Tiring?
- 3.15 What Is Energy at the Most Basic Level?
- 3.16 Why Is Stored Energy Just Frozen Motion?
- 3.17 What Is the Universe’s Background Noise?
- 3.18 Why Can Real Light Speed Slowly Drift?
- 3.19 Why Is Measured Light Speed Always c?
- 3.20 What Really Sets the Universe’s Speed Limit?
- 3.21 What Is Time When You Strip Away Clocks?
- 3.22 Why Does Moving Fast Make Time Run Slow?
- 3.23 Why Does Strong Gravity Make Time Crawl?
- 3.24 How Could We Jump Forward into the Future?
- 3.25 Why Can’t Going Faster Than Light Undo Time?
Appendix-5. Boiling Black Holes|S04 script ((V5.05)
- 4.1 Why Isn’t a Black Hole Just Empty Space?
- 4.2 How Can a Black Hole Leak Through Tiny Pores?
- 4.3 How Does the Piston Make Black Holes Breathe?
- 4.4 How Does the Shredding Belt Rip Particles Apart?
- 4.5 Why Is the Core a Boiling Filament Soup?
- 4.6 Why Is the Event Horizon Only a Shadow Line?
- 4.7 Why Does Light Fall Down Black Hole Slopes?
- 4.8 Why Do Black Hole Shadows All Look the Same?
- 4.9 Why Are Giant Black Holes Calm but Dangerous?
- 4.10 Why Do Big Black Holes Heat Their Own Skins?
- 5.1 Why Is Space Bright Around Black Holes?
- 5.2 How Do Black Holes Straighten Particle Beams?
- 5.3 Why Are Black Hole Jets So Straight?
- 5.4 How Can Jets Travel So Far from Black Holes?
- 5.5 How Do Black Holes Shave Matter into Filaments?
- 5.6 How Do Black Holes Stamp Out Clear Rhythms?
- 5.7 Why Don’t Black Holes Erase Information?
- 5.8 Why Does Time Nearly Freeze Near Black Holes?
- 5.9 How Do Black Holes Sculpt Whole Galaxies?
- 5.10 How Do Black Holes Take Stars Apart Stepwise?
- 6.1 How Do Unstable Particles Fake Dark Matter?
- 6.2 Why Can Redshift Arise Without Space Expanding?
- 6.3 How Do Black Holes Etch the Cosmic Web?
- 6.4 How Do Black Holes Bias the Direction of Time?
- 6.5 How Can Tension Alone Collapse into Black Holes?
- 6.6 Why Could Black Holes Form Before Any Stars?
- 6.7 Why Are Black Hole Mergers So Loud?
- 6.8 Could a Black Hole Core Start a New Universe?
- 6.9 Why Don’t Black Holes Explode When They Die?
- 6.10 Could the Universe End in a Filament Sea?
Appendix-6. Fields & Patterns|S07 script (V5.3)
- 7.1 What Is a Field, Really?
- 7.2 Why Vacuum Isn't Really Empty
- 7.3 Why Everything Slides into Gravity Wells
- 7.4 Electric vs Magnetic: Straight vs Swirl
- 7.5 Fields Are the Ocean, Particles Are Whirlpools
- 7.6 Stop Treating Fields Like Things
- 7.7 Why Charges Pull: Space Gets Stretched
- 7.8 Why Magnets Bend Moving Electrons
- 7.9 Where a Capacitor Stores Energy
- 7.10 Near-Field vs Far-Field: Two Modes
- 7.11 What Iron Filings Really Draw
- 7.12 Waveguides: When a Field Can't Escape
- 7.13 What a 'Gravity Field' Really Means
- 7.14 Where 'Stored Energy' Really Is
- 7.15 Why Clocks Run Faster on Mountains
- 7.16 The Horizon Is a Thin, Stretched Shell
- 7.17 From CMB Spots to the Cosmic Web
- 7.18 Could 'c' Change with the Universe?
- 7.19 Why Particles Feel Different Forces
- 7.20 How Fields Make Particles Find a Route
- 7.21 Why Metal Reflects, Glass Passes Light
- 7.22 Superconductors: One Giant Coherent Flow
- 7.23 Could 'Constants' Drift Over Cosmic Time?
- 7.24 How Fields Store Information Like a Disk
- 7.25 How Cosmic Rays Follow Invisible Highways
- 7.26 Antennas and Lasers: Pick One Mode
- 7.27 How Jets Form: Fields Make Tiny Corridors
- 7.28 Real Field Tech We Already Use
- 7.29 Cosmic Strings and Domain Walls Explained
- 7.30 Fields Set the Stage-Next: What Is Force?
Appendix-7. Forces & Slopes|S08 script (V5.3)
- 8.01 What Really Moves You (Not 'Force')
- 8.02 Newton's F=ma, in Plain Words
- 8.03 Why Motion Keeps Going Without a Push
- 8.04 Why 'Equilibrium' Is a Hidden Ledger
- 8.05 Where Energy Goes When You Push
- 8.06 Why Nature Chooses Least Action
- 8.07 Where 'Fake' Forces Come From
- 8.08 Gravity Without a 'Pulling' Force
- 8.09 Weightlessness: When the Floor Stops Pushing
- 8.10 Energy Never Vanishes-But What Is It?
- 8.11 What Momentum Conservation Actually Means
- 8.12 What 'Normal Force' Really Is
- 8.13 Why Springs Snap Back to Length
- 8.14 Why Some Things Slide and Others Stick
- 8.15 Tension: How Force Travels Down a Rope
- 8.16 Why Every Force Comes in a Pair
- 8.17 Centrifugal vs Coriolis: Rotating Frames
- 8.18 Why Things Float: Pressure Wins
- 8.19 What Happens in a Split-Second Impact
- 8.20 The Four-Force Mess in Textbooks
- 8.21 How Four Forces Become One Map
- 8.22 Why Nucleons Won't Separate
- 8.23 What a Gluon Might Actually Be
- 8.24 Why High-Energy Quarks Create Particle Rain
- 8.25 Why the Weak Force Changes Flavor
- 8.26 What W and Z Bosons Really Do
- 8.27 Electric Charge: A Space-Texture Sprayer
- 8.28 Inside a Light Bulb: Where Photons Come From
- 8.29 After Unification, Gravity Looks Ordinary
- 8.30 Why Spacetime Could Be Grainy
- 8.31 Tidal Forces: The Steepness That Rips
- 8.32 What We See When Spacetime Rings
- 8.33 Vacuum Effects Without Virtual Pairs
- 8.34 Extreme Magnetism on Neutron Stars
- 8.35 From Nuclei to Neutron Stars: Same Fight
- 8.36 How One Rhythm Can Break Structures
- 8.37 Before Forces: The Universe Was Boiling
- 8.38 A Force Desert at the Universe's Edge?
- 8.39 The Silent Hole Idea: A Force Mute Zone
- 8.40 All Forces on One Simple Map
Appendix-8. Quantum World|S9 script (V6.0)
- 9.01: What If Quantum Physics Is a Sea Map?
- 9.02: How Can Double Slits Draw Zebra Stripes?
- 9.03: Why Does Which‑Path Kill Interference?
- 9.04: How Does Entanglement Share Rules, Not Signals?
- 9.05: Why Can’t Entanglement Send Messages?
- 9.06: How Does Tunneling Slip Through Walls?
- 9.07: Why Can Two Barriers Tunnel Better?
- 9.08: Can Watching Freeze a Quantum Change?
- 9.09: How Can Watching Speed Up Decay?
- 9.10: Why Does the World Look Classical?
- 9.11: Is Uncertainty a Price Tag?
- 9.12: Why Do Empty Plates Attract?
- 9.13: Why Are Qubits So Fragile?
- 9.14: How Can an Echo Undo Dephasing?
- 9.15: What If You Measure Continuously?
- 9.16: Why Does “Spontaneous” Emission Happen?
- 9.17: Why Does Light Need a Threshold to Kick Electrons?
- 9.18: Why Does Compton Scattering Redshift Light?
- 9.19: How Can Light Cross a “Forbidden” Gap?
- 9.20: Near Field vs Far Field—Why Distance Changes Everything
- 9.21: The Wave‑Packet Driving Rules
- 9.22: Why Most “Light” Never Gets Far
- 9.23: Why Superfluids Flow Like Cheaters
- 9.24: Why Superconductors Have Zero Resistance
- 9.25: Why Do Qubits Feel Like Glass Bridges?
- 9.26: How Does Dynamic Decoupling Beat Noise?
- 9.27: Why Is a SQUID So Crazy Sensitive?
- 9.28: Why Can Defects Make Superconductors Better?
- 9.29: Is Quantum Computing Really “Parallel Universes”?
- 9.30: Does a Particle “Take All Paths”?
- 9.31: Renormalization Isn’t “Sweeping Infinity”
- 9.32: Hamiltonians Are Ledgers, Not Gods
- 9.33: Gauge Is a Ruler Choice
- 9.34: S‑Matrix vs Local Fields
- 9.35: Vacuum Isn’t One Single Thing
- 9.36: The Wavefunction Is a Blueprint
- 9.37: Is Collapse a Magic Snap?
- 9.38: Why Is Probability |ψ|²?
- 9.39: Is Randomness Just Ignorance?
- 9.40: Can Weak Measurement Steal a Whisper?
- 9.41: Are Observers Inside the System?
- 9.42: What Did Bell Really Kill?
- 9.43: CHSH—Why Four Angles Break “Prewritten Answers”
- 9.44: Entanglement Swapping—How Strangers Become Linked
- 9.45: Quantum Teleportation—What Actually Gets “Sent”
- 9.46: Quantum Eraser—How Stripes “Return” Without Time Travel
- 9.47: Zeno vs Anti‑Zeno—Measurement as Brake or Gas
- 9.48: The Quantum User Manual—Four Tools That Explain Everything
- 9.49: Double‑Slit, Entanglement, Tunneling—One Map, Three Faces
- 9.50: Finale—Ten Lines to Understand Quantum, Plus Testable Fingerprints
Appendix-9. Macroscopic Cosmos|S10 script (V6.0)
- 10.0 What If the Universe Has a Real Boundary?
- 10.A1 Did the Universe Ever Expand at All?
- 10.A2 Is Redshift a Timing Effect, Not Speed?
- 10.A3 Why Do We Treat Redshift Differently Far Away?
- 10.A4 Does Expansion Explain Why the Universe Cooled?
- 10.A5 Did We Measure the Universe's Temperature?
- 10.A6 Could the Universe Have a Physical Edge?
- 10.A7 Are We Treating Cosmology Like a Religion?
- 10.A8 Do Cosmic Numbers Depend on Our Measuring Stick?
- 10.A9 Could Changing Units Mimic Cosmic Change?
- 10.A10 Is 'c' a Definition, Not a Measured Speed?
- 10.A11 Which Came First: the Meter or 'c'?
- 10.A12 Could the 'Constants' Drift Over Cosmic Time?
- 10.A13 Do Universe Models Fit Data or Tell Stories?
- 10.B1 Was the Early Universe a Boiling Medium?
- 10.B2 What If Every Particle Is a Tiny Ring?
- 10.B3 Why Isn't Light a Flying Particle?
- 10.B4 Could All Four Forces Be One System?
- 10.B5 Can Short-Lived Particles Create Extra Gravity?
- 10.B6 Does the Universe Change by Relaxing Tension?
- 10.B7 What If Our Cosmology Story Is Missing Pieces?
- 10.B8 How Could a Real Edge Form Around the Universe?
- 10.B9 What If a Black Hole Core Is Boiling Inside?
- 10.B10 What Is a 'Silent Hole' Bubble in Space?
- 10.B11 Could Our Universe Be a Black Hole Overflow?
- 10.B12 Could the Universe End at a Real Boundary?
- 10.B13 Do All Waves Come from One Underlying Medium?
- 10.B14 Do Measurements Change the World They Measure?
- 10.B15 Is Modern Physics Due for a Major Upgrade?
- 10.B16 Why Do New Universe Ideas Matter to Everyone?
- 10.C1 Could a 'Parent' Black Hole Create a Universe?
- 10.C2 Could Ordinary Black Holes Seed New Universes?
- 10.C3 What Could Create a Physical Edge in Space?
- 10.C4 What Would a Real Universe Edge Look Like?
- 10.C5 Do Four Big Puzzles Point to a Universe Edge?
Docs-Data Fitting Report (V6.0)
- GPT (001-050)
- GPT (051-100)
- GPT (1001-1050)
- GPT (101-150)
- GPT (1051-1100)
- GPT (1101-1150)
- GPT (1151-1200)
- GPT (1201-1250)
- GPT (1251-1300)
- GPT (1301-1350)
- GPT (1351-1400)
- GPT (1401-1450)
- GPT (1451-1500)
- GPT (1501-1550)
- GPT (151-200)
- GPT (1551-1600)
- GPT (1601-1650)
- GPT (1651-1700)
- GPT (1701-1750)
- GPT (1751-1800)
- GPT (1801-1850)
- GPT (1851-1900)
- GPT (1901-1950)
- GPT (1951-2000)
- GPT (201-250)
- GPT (251-300)
- GPT (301-350)
- GPT (351-400)
- GPT (401-450)
- GPT (451-500)
- GPT (501-550)
- GPT (551-600)
- GPT (601-650)
- GPT (651-700)
- GPT (701-750)
- GPT (751-800)
- GPT (801-850)
- GPT (851-900)
- GPT (901-950)
- GPT (951-1000)
Docs-Technical WhitePaper (V6.0)
- 01-EFT.WP.Core.Terms v1.0
- 02-EFT.WP.Core.Equations v1.1
- 03-EFT.WP.Core.Parameters v1.0
- 04-EFT.WP.Core.Metrology v1.0
- 05-EFT.WP.Core.Errors v1.0
- 06-EFT.WP.Core.DataSpec v1.0
- 07-EFT.WP.Core.Threads v1.0
- 08-EFT.WP.Core.Sea v1.0
- 09-EFT.WP.Core.Density v1.0
- 10-EFT.WP.Core.Tension v1.0
- 11-EFT.WP.Core.DrawingKinetics v1.0
- 12-EFT.WP.Methods.Repro v1.0
- 13-EFT.WP.Methods.SimStack v1.0
- 14-EFT.WP.Methods.Inference v1.0
- 15-EFT.WP.Methods.Falsification v1.0
- 16-EFT.WP.Methods.Cleaning v1.0
- 17-EFT.WP.Methods.Imaging v1.0
- 18-EFT.WP.Methods.CrossStats v1.0
- 19-EFT.WP.Methods.SynthData v1.0
- 20-EFT.WP.Metrology.TimeBase v1.0
- 21-EFT.WP.Metrology.Sync v1.0
- 22-EFT.WP.Metrology.Instrument v1.0
- 23-EFT.WP.Metrology.PathCorrection v1.0
- 24-EFT.WP.Particle.TopologyAtlas v1.0
- 25-EFT.WP.STG.Dynamics v1.0
- 26-EFT.WP.STG.Lensing v1.0
- 27-EFT.WP.Packets.Light v1.0
- 28-EFT.WP.Propagation.PathRedshift v1.0
- 29-EFT.WP.TBN.Measurement v1.0
- 30-EFT.WP.Propagation.TensionPotential v1.0
- 31-EFT.WP.BH.TensionWall v1.0
- 32-EFT.WP.Cosmo.LayeredSea v1.0
- 33-EFT.WP.Cosmo.EarlyObjects v1.0
- 34-EFT.WP.Astro.Acceleration v1.0
- 35-EFT.WP.EDX.OrientedTension v1.0
- 36-EFT.WP.EDX.Current v1.0
- 37-EFT.WP.EDX.HighSpeed v1.0
- 38-EFT.WP.EDX.EMI v1.0
- 39-EFT.WP.Plasma.Confinement v1.0
- 40-EFT.WP.Materials.Superconductivity v1.0
- 41-EFT.WP.Comms.Navigation v1.0
- 42-EFT.WP.Heat.Decoherence v1.0
- 43-EFT.WP.Data.DatasetCards v1.0
- 44-EFT.WP.Data.ModelCards v1.0
- 45-EFT.WP.Data.Pipeline v1.0
- 46-EFT.WP.Data.Benchmarks v1.0
- 47-PTN Template v1.0
- 48-Experimental Protocol Card Template v1.0
- 49-Error Budget Card Template v1.0
- 50-Parameter Registration Card Template v1.0
- 51-Pipeline Card Template v1.0
- 52-Dataset Card Template v1.0
- 53-Model Card Template v1.0
- 54-Reproducibility Checklist Template v1.0
- 55-Decision & Change Log Template v1.0
- 56-Report-Level Methods Appendix Template v1.0