автордың кітабын онлайн тегін оқу  Singular Physics as the Missing Link

Valeriy Zhiglov

Contents

Singular Physics as the Missing Link in the Architecture of the Universe

Abstract

Modern physics is confronted with fundamental contradictions: the nature of dark energy and dark matter remains elusive, a quantum theory of gravity is absent, and the singularities of black holes and the Big Bang indicate the incompleteness of existing models. This review proposes a new paradigm — Singular Physics — as the missing link in the architecture of the Universe.

The approach is based on a multilevel structure of reality, where our 3+1-dimensional Universe emerges from a phase transition of a fundamental 2D quantum vacuum. The article provides a detailed analysis of an extended theory of relativity, allowing for superluminal (v> c) states and tachyonic fields, alongside modified quantum mechanics with a decoherence operator for wave function collapse in strong gravitational fields.

We present and interpret results from laboratory modeling (Technion experiment, 2026) and astronomical observations (object 1ES 1927+654, event AT2018cow) as evidence for phase transitions and quantum explosions. A hierarchical model is proposed: a 1D primary singularity, a 2D quantum vacuum, and a 3D crystallized space-time. The framework offers a fresh perspective on the dynamics of time, entropy asymmetry, and the quantum nature of reality.

Keywords: singular physics, extended relativity, tachyons, quantum decoherence, multilevel Universe, superluminal barrier, phase transitions, cosmology.

Introduction: The Fundamental Crisis and the Role of Singular Physics

1.1. Statement of the Problem: A Review of Unresolved Questions in Modern Physics

Despite its remarkable successes in describing both the microcosm and the macrocosm, modern theoretical physics is experiencing a profound conceptual crisis. This crisis manifests as a series of fundamental contradictions and unresolved problems that challenge the completeness and internal consistency of existing models.

Key unresolved questions include:

— The Problem of Dark Matter and Dark Energy. Observational astronomy convincingly demonstrates that visible (baryonic) matter constitutes only about 5% of the total energy density of the Universe. The remaining 95% is attributed to dark matter (27%) and dark energy (68%). The nature of these components remains unknown. Dark matter is not described by the Standard Model of particles, and dark energy, responsible for the accelerated expansion of the Universe, lacks a satisfactory explanation within the frameworks of General Relativity and quantum field theory.

— The Problem of Singularities. General Relativity (GR) predicts the existence of gravitational singularities — points of infinite density and space-time curvature. Such objects arise at the center of black holes and at the initial moment of the Big Bang. At these points, known physical laws cease to function, indicating the incompleteness of GR and the need for a new, more general theory.

— The Absence of a Quantum Theory of Gravity. The Standard Model and GR — the two greatest theories of the 20th century — are fundamentally incompatible. Attempts to unify them within a quantum theory of gravity (e.g., string theory, loop quantum gravity) have not yet led to a verifiable and generally accepted model. This hinders our understanding of early Universe physics, the internal structure of black holes, and the very nature of space-time.

These problems indicate that modern physics has reached the limits of applicability of its fundamental paradigms. Resolving these contradictions requires not merely modifying existing theories but revising the very foundations of our understanding of reality.

In this context, singular physics is proposed as a new conceptual framework capable of becoming the missing link in the architect