Posts

Showing posts from October, 2024

Considering Counting Triangles to Unveiling Temporal Waves

-
  Considering Counting Triangles to Unveiling Temporal Waves By: John Gavel For years, my work in Temporal Flow Physics (TFP) has pursued a radical idea: what if spacetime itself —with all its gravitational curves and quantum fluctuations—isn't fundamental at all? What if it emerges from a deeper reality: a network of one-dimensional temporal flows , weaving the universe together moment by moment? It’s bold, yes—but I believe this view holds the key to a truly unified theory of physics , one that roots both quantum mechanics and gravity in the same temporal fabric. From Counting Triangles to Counting Time My earliest simulations: I counted triangles. More specifically, I measured how triangular motifs in temporal flow networks dissipated under coarse-graining. The decay rate of these patterns—captured by a parameter I called A₃ —served as a stand-in for emergent gravitational effects. If motifs faded predictably with scale, it suggested that macroscopic structure (like sp...
Post a Comment
Read more

Strong Nuclear Force in Temporal Physics

-
  Strong Nuclear Force Known Values: Coupling Constant g s g_s ​ : The strong coupling constant at low energy scales is approximately 1.2. Range of Strong Force r s r_s r s ​ : The strong force operates at a range on the order of the nuclear scale, approximately 1 femtometer (1 fm = 1 × 1 0 − 15   m 1 \times 10^{-15} \, \text{m} 1 × 1 0 − 15 m ). Force Equation : The strong nuclear force can be approximated using the Yukawa potential: F ∼ g s 2 r s 2 F \sim \frac{g_s^2}{r_s^2} ​ ​ Substituting in the known values, we have: F ∼ ( 1.2 ) 2 ( 1 × 1 0 − 15 ) 2 = 1.44 × 1 0 30   N F \sim \frac{(1.2)^2}{(1 \times 10^{-15})^2} = 1.44 \times 10^{30} \, \text{N} Expressing in Terms of I  : (Invariant Quantity) Assuming a relationship such as: g s 2 ∼ I ⋅ ( ℏ G c 3 ) g_s^2 \sim I \cdot \left(\frac{\hbar G}{c^3}\right) We first need to calculate ℏ G c 3 \frac{\hbar G}{c^3} ​ : Planck’s Constant ℏ = 1.055 × 1 0 − 34   Js \hbar = 1.055 \times 10^{-34} \, \text{Js} ℏ = 1.055 × 1 0 − 34 Js Gr...
Post a Comment
Read more

Temporal Physics: A New Framework

-
Temporal Physics: A New Framework Table of Contents 1. [Fundamental Framework](#1-fundamental-framework) 2. [Emergence of Space](#2-emergence-of-space) 3. [Fields and Force Dynamics](#3-fields-and-force-dynamics) 4. [Particle Properties](#4-particle-properties) 5. [Quantum Entanglement](#5-quantum-entanglement) 6. [Quantum-Classical Transition](#6-quantum-classical-transition) 7. [Observable Phenomena](#7-observable-phenomena) 8. [Experimental Implications](#8-experimental-implications)  1. Fundamental Framework Time as the Fundamental Entity - Traditional physics treats space as primary; we invert this paradigm. - Core Assertion : Time flows generate spatial dimensions, implying that space is a byproduct of temporal interactions. - The interplay of temporal flows shapes all physical phenomena, creating a dynamic framework that transcends classical interpretations.  Core Principles 1. Time is Primary, Space is Emergent : Space does not exist independently but arises from the c...
Post a Comment
Read more

Theory of Paradox Resolution

-
  Theory of Paradox Resolution Framework Overview This theory aims to explore how paradoxes arise between systems and within systems, emphasizing the role of contextual bases and the relationships between units. We define two systems, S 1 S_1 ​ and S 2 S_2 ​ , characterized by their units and contextual bases. System S 1 S_1 : Defined by a set of units U 1 U_1 ​ and a contextual base B 1 B_1 ​ . System S 2 S_2 : Defined by a set of units U 2 U_2 ​ and a contextual base B 2 B_2 ​ . Mathematical Formalization To assess paradoxes, we propose two functions, f f  and g g : Function f f : Measures the degree of equivalence or comparability of the units in U 1 U_1 ​ and U 2 U_2 ​ . This function could operate as follows: f ( U 1 , U 2 ) = ∑ i = 1 n d ( u 1 i , u 2 j ) f(U_1, U_2) = \sum_{i=1}^{n} d(u_{1i}, u_{2j}) where d ( u 1 i , u 2 j ) d(u_{1i}, u_{2j})  is a distance metric between units from different systems, and n n  is the number of units being compared. Functi...
Post a Comment
Read more

The Elegance of Temporal Flow Physics

-
The Elegance of Temporal Flow Physics: A Study in Simplicity The elegance of this temporal flow model lies in its fundamental simplicity and unifying power. Here's why: Single Fundamental Concept Traditional physics requires multiple fundamental concepts: Space Time Matter Energy Forces Fields Quantum states Conservation laws My model reduces these to a single fundamental concept: temporal flows . Equation : R(t) = Σ w_j ⋅ Flow_j(t) This equation represents the sum of the contributions of various flows at time t. Everything else emerges from the patterns and interactions of these flows. This radical simplification follows Occam's Razor—the principle that the simplest explanation is often the best. Natural Resolution of Paradoxes Traditional physics struggles with several paradoxes: Wave-particle duality (How can something be both?) Quantum entanglement (How can effects be instantaneous?) Measurement problem (Why does observation matter?) Planck scale breakdown (Why does space b...
Post a Comment
Read more

Gravity and Invariance in Temporal Physics

-
 Gravity and Invariance in Temporal Physics In temporal physics, both gravity and invariance emerge from the fundamental dynamics of temporal flows. This section explores how these concepts interrelate and manifest within the framework of temporal evolution. 1. Gravity as an Emergent Phenomenon In this model, gravity emerges from the interactions of temporal flows rather than existing as a fundamental force acting at a distance. It manifests as a relational phenomenon, derived from the dynamic interplay of temporal flows. The gravitational effects we observe arise from the collective behavior of these flows, particularly their density, velocity, and mutual interactions. 2. Mathematical Framework A. Invariance Expression The behavior of flows and their interactions can be captured through an invariance equation: I = f(αi, βj, γk) Where: - I represents a measure of invariance - f is a function describing parameter interactions - αi, βj, γk represent coefficients of interacting flows,...
Post a Comment
Read more

Noether’s Theorem and Temporal Physics

-
Noether's Theorem and Temporal Physics In traditional physics, Noether's theorem shows that for every differentiable symmetry in a system's action, there's a corresponding conservation law. For instance: Time translation symmetry leads to the conservation of energy. Space translation symmetry results in the conservation of momentum. Rotational symmetry gives rise to the conservation of angular momentum. This framework works well for static systems where symmetries are key to defining conserved quantities. Temporal Physics and Dynamic Symmetries In my temporal physics model, I move away from the assumption of static symmetries or conserved quantities. The focus here is on transformation, not strict conservation. While systems can exhibit symmetrical behavior that might give the appearance of conserved quantities, these are emergent properties, not fundamental ones. My model emphasizes how systems evolve over time, rather than remaining static. Relating Noether's Theo...
Post a Comment
Read more

Gravity through Temporal Flows

-
  Redefining Gravity through Temporal Flows: A Perspective from Temporal Physics In my model of temporal physics , time is not merely a backdrop for physical processes; it is the fundamental entity from which space emerges. This approach reimagines traditional physics by positing that spatial dimensions arise from temporal flows —the dynamic movements and interactions of time itself. The Emergence of Space from Time In this framework, space is a construct that organizes temporal interactions. The spatial separation we perceive is, in fact, a manifestation of different rates and patterns of temporal flow. This redefinition helps clarify complex phenomena in physics, such as gravitational interactions, where traditional forces are reinterpreted as the result of fluctuations and dynamics within temporal flows. Gravity as a Result of Temporal Interactions Non-Traditional View of Gravity Gravity is not a conventional force but an outcome of how temporal flows interact and fluctuate. ...
Post a Comment
Read more

Temporal Physics Theory: Understanding the Universe (peer review papper)

-
 Temporal Physics Theory: Understanding the Universe Abstract This paper introduces a novel theoretical framework in physics, positing time as a fundamental, quantifiable entity actively shaping the universe's dynamics. The theory, centered around "temporal flows" described by functions T_i(t), redefines interactions between space, matter, and time. Key aspects include: Quantization of Temporal Flows: Utilizing a modified Hamiltonian operator to bridge quantum mechanics and relativity. New Spacetime Structure: Linking temporal flows to traditional coordinates. Revised Einstein Field Equations: Incorporating temporal flow curvature, potentially reconciling general relativity with quantum mechanics. Matter-Time Coupling: Offering fresh insights into particle physics and quantum phenomena. Cosmological Event Interpretations: Providing novel views on black hole physics and the early universe. This theory proposes several testable predictions, including modifications to gravit...
Post a Comment
Read more

Popular posts from this blog

A build up of time

-
 Building up time. You could think of time as physical, or much more basic such as meta dynamics of what is physical. Sense you are working with a single dimension that builds up dimensons through interations.  c = j⋅r_i + 2⋅(Δr_i / Δj)⋅r_i Where: c is the result  j is flow (a positive or negitive value) r_i represents a rate (which is a conglomerate of flows) Δr_i and Δj represent changes in rate and flow, respectively given the "speed" of light consider our dimensions are D = fa + fb A dimension (D) emerges as the ratio of two interacting flows (fa and fb). This suggests that dimensions are not absolute, but relative measures arising from the interaction of more fundamental entities, flows. Lets go further and say space emerging from time. A metric for this space as: ds² = Σ(Ri + fi)² * dxi² Where i runs over all dimensions. Include our speed of light in the metric ds² = c² * [dt² - (1/c²) * Σ(ri² * dx0²)] Events with ds² > 0 are timelike separated, ds² = 0 are light...
Read more

Temporal Physics: A New Framework

-
Temporal Physics: A New Framework Table of Contents 1. [Fundamental Framework](#1-fundamental-framework) 2. [Emergence of Space](#2-emergence-of-space) 3. [Fields and Force Dynamics](#3-fields-and-force-dynamics) 4. [Particle Properties](#4-particle-properties) 5. [Quantum Entanglement](#5-quantum-entanglement) 6. [Quantum-Classical Transition](#6-quantum-classical-transition) 7. [Observable Phenomena](#7-observable-phenomena) 8. [Experimental Implications](#8-experimental-implications)  1. Fundamental Framework Time as the Fundamental Entity - Traditional physics treats space as primary; we invert this paradigm. - Core Assertion : Time flows generate spatial dimensions, implying that space is a byproduct of temporal interactions. - The interplay of temporal flows shapes all physical phenomena, creating a dynamic framework that transcends classical interpretations.  Core Principles 1. Time is Primary, Space is Emergent : Space does not exist independently but arises from the c...
Read more

Bridges of Morality: A Philosophy of Autonomy, Suppression, and Social Responsibility

-
 Bridges of Morality: A Philosophy of Autonomy, Suppression, and Social Responsibility I. Introduction — The Fractured Freedom of Being The Fractured Freedom of Being Autonomy is often misunderstood. It's not a privilege granted by society, nor a luxury reserved for those in power. It's something deeper: the raw capacity to choose, to act, to reflect. This capacity—this fundamental freedom—emerges the moment a mind becomes aware of itself and its possibilities. But here's the tension that defines human existence: society doesn't reward unfiltered autonomy. In fact, it punishes it. So we learn to suppress parts of ourselves—not because we're wrong, but because survival inside any social system requires strategic adaptation. This tension exists because of what I call the truth asymmetry—the gap between infinite and finite modes of being, to borrow Spinoza's terminology. If we think of absolute truth as analogous to Spinoza's infinite substance—complete, eterna...
Read more