Dist Babble

Temporal Flow Physics and the Myth of Fundamental Indeterminism In contemporary physics, indeterminism often appears baked into the structure of quantum mechanics. Yet the Temporal Flow Physics (TFP) framework offers a radically different perspective: indeterminacy is not fundamental—it emerges statistically from the vast configuration space of interacting quantized 1D temporal flows. This blog explores how TFP reconciles deterministic local dynamics with statistical entropy, decoherence, and even Prigogine’s notion of dissipative structures, showing that what appears probabilistic is the result of segmental flow misalignment, not fundamental randomness. 1. From Many Flows to Entropy In TFP, the fundamental object is a 1D quantized temporal flow F i ( t ) F_i(t) . Each flow represents a causal chain of temporal events. Space, and therefore locality, emerges from comparisons between these flows. Let us denote a system of N N flows as: { F i ( t ) } i = 1 N \{F_i(t)\}_{i=1}^N Lo...

Temporal Flow Physics:  Numerical Validations and Physical Insights How treating time as fundamental could unify black holes, quantum entanglement, and the cosmos itself Introduction: Time as the Building Block of Reality Imagine if time—not space—were the true foundation of the universe. Temporal Flow Physics (TFP) proposes just that: a world where  quantized fragments of time interact to generate space, matter, and gravity . In this framework, everything from black holes to quantum entanglement emerges from the dynamics of these primordial temporal flows. But does this bold idea hold up to scrutiny? Let’s examine the numbers. 1. Black Holes: Where Time Flows Collapse The Standard View Black hole entropy, as described by Bekenstein and Hawking: S BH = A 4 G ℏ ≈ 1.45 × 10 54   J/K ( for a solar-mass black hole ) S BH ​ = 4 G ℏ A ​ ≈ 1.45 × 1 0 54 J/K ( for a solar-mass black hole ) where  A A  is the horizon area. TFP’s Revelat...