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Temporal Physics: Temporal Flow and Dynamics Abstract In this paper, I present a new perspective on physical interactions, based on temporal flows . By treating time as a fundamental construct rather than space or matter, I propose a model where energy, mass, and fields emerge from interactions of time itself. This framework offers new insights into classical and quantum mechanics, black hole dynamics, and gravitational waves. I introduce a set of mathematical equations that describe these temporal flows , their interactions, and their implications for our understanding of the universe. 1. Introduction The Motivation The traditional models of physics—classical mechanics, quantum mechanics, and general relativity—have done an excellent job of describing physical phenomena. However, they often rely on an underlying assumption that space is more fundamental than time, with the understanding that matter and energy interact within this space. But I believe that time itself is the more funda...

Introduction and Foundational Framework Spacetime is fundamentally composed of temporal flows. In this model, temporal flows are defined as: τ i ( t ) = A i ϕ i ( t ) where: A i A_i  represents the amplitude, quantifying the strength of the flow. ϕ i ( t ) \phi_i(t)  is a normalized time-dependent function, with max ⁡ ∣ ϕ i ( t ) ∣ = 1 \max |\phi_i(t)| = 1 , capturing the shape of the flow. In this framework, temporal flows drive curvature and changes in the metric tensor g μ ν g_{\mu\nu} ​ , which manifests as spacetime in response to these temporal dynamics. 2. Quantum Field Theoretical Foundation 2.1 Field Theoretic Description Temporal flows are described within the context of quantum field theory using the Lagrangian density: L = 1 2 g μ ν ∂ μ τ i ∂ ν τ i − V ( τ i ) where V ( τ i ) V(\tau_i)  represents the potential associated with the temporal flows. 2.2 Quantum Entanglement Connection Temporal flows influence quantum entanglement through modifications to the dens...

Temporal Physics Quantum Gravity: A Modified Model Incorporating Temporal Flows State Evolution In traditional quantum gravity, the evolution of the quantum state is governed by the time-dependent Schrödinger equation: ψ ( t ) = e − i H t ℏ ψ ( 0 ) Here, the Hamiltonian H H  dictates the system's energy and dynamics, and time is treated as a passive parameter. This formulation assumes that time itself is merely a background parameter that doesn't actively influence the state evolution. In my model, time is treated as an active component influencing the evolution of quantum states. This is reflected in the modified evolution equation: ψ ( t ) = e − i ( H + f ( t ) ) t ℏ ψ ( 0 ) Here, the Hamiltonian H H  is augmented by a time-dependent term f ( t ) f(t) , representing a correction due to temporal dynamics. This correction reflects the active role of time in the quantum gravitational context, resulting in an altered evolution of the quantum state compared to traditional models....

 Temporal Physics; Temporal Dynamics Metric Basic Form g μ ν = η μ ν + ∑ i ( α i τ i ( t ) ⋅ τ i ( t ) ) Core Structure : Starts with the Minkowski metric η μ ν \eta_{\mu\nu} , modified by contributions from temporal flows. Flow Contributions : Each temporal flow τ i ( t ) \tau_i(t)  contributes to the metric, scaled by α i \alpha_i , which governs the strength of each flow. Purpose : Describes a linear addition of temporal effects to the spacetime structure. 2. Including Non-Linear Corrections g μ ν = η μ ν + ∑ i ( α i τ i ( t ) ⋅ τ i ( t ) + κ i ( τ i ( t ) ) ) Non-Linear Term ( κ i ( τ i ( t ) ) \kappa_i(\tau_i(t)) : Accounts for non-linear effects or interactions between flows. Captures higher-order corrections that are not simply quadratic. Purpose : Models more complex systems where flows interact non-linearly or have self-modifying behavior. 3. Temporal Flows and Spatial Dimensions g μ ν ( x , t ) = η μ ν + ∑ i ( α i τ i ( t ) ⋅ τ i ( t ) + β i ( x , t ) ) Spatial-Temp...