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Main Author: Moghaddami, Kash
Format: Recurso digital
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Published: Zenodo 2025
Online Access:https://doi.org/10.5281/zenodo.15515596
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author Moghaddami, Kash
author_facet Moghaddami, Kash
contents <p>This paper introduces a groundbreaking perspective that life’s molecular structures—DNA, RNA, proteins, and cell division—are not merely biochemical systems, but stable braid formations within a delay-saturated causal field. Using the Temporal Synchrony Gradient Gravity (TSGG) framework, it proposes that biological architecture emerges where spacetime’s delay gradients permit coherent braid resonance. The double helix, RNA folding, and mitosis are reinterpreted as manifestations of time-stabilizing geometry. Life is not just a chemical event—it is the resonance of time, braided into form.</p>
format Recurso digital
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publishDate 2025
publisher Zenodo
record_format zenodo
spellingShingle Biological Structures as Delay Braid Resonators: A TSGG Interpretation of DNA, RNA, and Cellular Geometry
Moghaddami, Kash
<p>This paper introduces a groundbreaking perspective that life’s molecular structures—DNA, RNA, proteins, and cell division—are not merely biochemical systems, but stable braid formations within a delay-saturated causal field. Using the Temporal Synchrony Gradient Gravity (TSGG) framework, it proposes that biological architecture emerges where spacetime’s delay gradients permit coherent braid resonance. The double helix, RNA folding, and mitosis are reinterpreted as manifestations of time-stabilizing geometry. Life is not just a chemical event—it is the resonance of time, braided into form.</p>
title Biological Structures as Delay Braid Resonators: A TSGG Interpretation of DNA, RNA, and Cellular Geometry
url https://doi.org/10.5281/zenodo.15515596