Dist Babble

Temporal Physics For years, I've been working on a model that challenges how we traditionally think about time and physics. It can be difficult to wrap your head around the idea that space, time, and the forces governing the universe might be far more intricate than what we've been taught. My model of temporal physics reimagines our understanding of the cosmos, focusing on the flow of time and how matter and energy emerge from its dynamics. In this post, I'll break down the core ideas of my model and explain how it diverges from traditional physics. The Core Idea: Time as a Dynamic Flow At the heart of my model lies a radical idea: time does not flow linearly. Instead, it consists of discrete, interacting "flows" that I refer to as temporal flows . These flows are responsible for the phenomena we perceive as space and matter. In my framework, space isn't a passive backdrop but a dynamic structure that emerges from the interplay of these flows. Time isn't ...

The Least Multiplication Principle in My Model of Temporal Physics In the exploration of my model of temporal physics, one of the key aspects I've focused on is how flows within time and space interact to create the structures we observe—especially particles and emergent phenomena like the Cosmic Microwave Background Radiation (CMBR). The underlying framework of my model suggests that interactions between these flows, particularly those governed by phase and amplitude, are governed by a principle of minimalism: the least multiplication principle . This principle, grounded in the idea of minimizing unnecessary computations or interactions, naturally arises when looking at how space and particles emerge. Temporal Waves and the Emergence of Space In my model, space isn’t a pre-existing backdrop or static construct. Instead, it emerges from the interaction of temporal flows. These flows are dynamic fields of temporal waves, where each flow is linked to a field φ \varphi  and its gradie...

Temporal Flows and Evolution In this, I aimed to work on how my model predicts the formation of particles through the interactions of temporal flows. My goal was to refine the details and highlight the key insight that flows are linear. As you’ll see, this linearity is crucial because nonlinear effects don't significantly alter the outcome as traditional models might suggest. Essentially, we're dealing with very small values of flows that accumulate over time, and this process remains consistent across the simulations I ran, supporting the idea that the dynamics work out similarly despite the complexity. Core Principles and Fundamental Equations 1. Temporal Flows and Evolution: Evolution Function L ( ϕ , ∇ ϕ ) : L(\phi, \nabla \phi): ϕ ( t + Δ t ) = ϕ ( t ) + L ( ϕ , ∇ ϕ ) \phi(t + \Delta t) = \phi(t) + L(\phi, \nabla \phi) Quantization in Planck Time: Temporal flows are quantized in steps of Planck time t P t_P , ensuring discrete evolution steps. This highlights how f...

  Integration of Renormalization and Decoherence in Temporal Flows In Temporal Physics, integrating renormalization and decoherence offers a framework for understanding how flows evolve, interact, and lose coherence over time. Let’s dive into how these concepts combine to enhance the model of temporal dynamics. Temporal Flows and Renormalization At the heart of this approach is the concept of flow-rescaling transformation, which serves as a key tool for renormalizing temporal flows. The basic idea is that the properties of a flow (denoted as f f ) can be rescaled by a factor Z ( Λ ) Z(\Lambda) , where Λ \Lambda  represents the scale at which the flow is observed. This transformation ensures that the flow behaves consistently across different scales: f ′ = Z ( Λ ) f , ∇ f ′ = Z ( Λ ) ∇ f f' = Z(\Lambda) f, \quad \nabla f' = Z(\Lambda) \nabla f Here, Z ( Λ ) Z(\Lambda)  acts as a scale-dependent renormalization factor, rescaling both the flow and its gradient. But how does ...

Emergent Temperature and Pressure in a Flow-Based Model of Physics Introduction In modern physics, space and time are often treated as fundamental structures, with thermodynamic properties like temperature and pressure emerging from microscopic interactions. However, in my model, these properties are not just statistical phenomena but arise from a deeper, underlying flow field. This blog post explores how temperature and pressure naturally emerge from these flows, showing that thermodynamics is a direct consequence of flow dynamics rather than an independent framework imposed on top of fundamental physics. 1. The Basic Framework In this model, the universe is described by a flow field—a scalar or multi-component field that gives rise to emergent space, time, and thermodynamic properties. Instead of treating space and time as pre-existing, they emerge from weighted sums of flow components: X = ∑ i α i   ϕ i , t eff = ∑ i δ i   ϕ i , X = \sum_i \alpha_i\, \phi_i, \quad t_{\text{eff}} = \...