Theory of Elasticity of Physics

A unified framework proposing that all physical laws have elastic properties—that what we call "laws of physics" are not rigid constraints but flexible principles that can stretch under extreme conditions. Theory of Elasticity of Physics suggests that constants vary, that symmetries break and reform, that the fabric of reality itself is stretchy. The theory identifies the elastic limits of physics: how far laws can stretch before they break, what happens at the breaking point, and how physics recovers.

A framework proposing that thermodynamic laws have elastic properties—that entropy, energy, and temperature can stretch, compress, and recover under extreme conditions. Theory of Elasticity of Thermodynamics suggests that the second law (entropy increases) is elastic: you can stretch it locally, compress it elsewhere, but the total elastic limit holds. The theory explains how life (local order) exists in a universe tending toward disorder: thermodynamics stretches, but doesn't break.

A speculative framework proposing that causality has elastic properties that allow it to stretch, compress, or deform under FTL conditions without breaking. The Theory of Elasticity of Causality in FTL Scenarios suggests that cause-effect relationships can stretch across spacetime in ways that look like paradox but are actually elastic deformations—like a rubber band stretched but not snapped. When the FTL journey ends, causality snaps back to its proper order. The theory identifies causality's elastic limits: how far can you stretch it before it breaks? FTL might be possible within those limits, but exceed them and causality snaps—with unknown consequences.