The Big Now: A Reassmessment of Cosmological Origins Using Advanced Mathematics To Map Atomic Continuity (Between Points)

Abstract

This article addresses "The Big Bang" misnomer in terms of general priority and living populations, presenting weather journalism, for instance, as additional physical evidence in favor of "The Big Now" as suggests atomic continuity between (generalizing): 1 + 1 = 2 points; a.k.a. 2√2 = 🔢. In terms of advanced, foundational mathematics: appealing to Cantor's diagonal argument, Gödel's mathematical Platonism, we also have well-documented physics equations mapping a consistent framework identified here as "The Big Now". Additionally, this article emphasizes the maximum survival value of thermodynamic literacy as our understanding of surface immune systems will continue to map all plants and animals on this solar-centric, living planet, Earth.

Introduction

The Big Bang model has long dominated cosmological discourse, positing an initial explosion from a singularly impossible (zero-probability) origin. In contrast, all additional evidence ([1 + 1 points = 2 points] ≠ [-1=0 points]) supports "The Big Now": a model that aligns with advanced mathematical theories, emphasizes atomic continuity, and confirms general interconnectedness by decentralizing false, zero-origin stories as human-centric, false property "birthday" claims: (-1 year = year zero). That is: Cantor's diagonal argument and Gödel's mathematical Platonism remain consistent as foundational concerning all equations published in quantum mechanics, molecular biology and general, cosmological relativity: The Big Now model's comprehensive approach also aligns with our ongoing humanitarian efforts, toward thermodynamic hope as all bilateral plants and animals will continue to resist thermodynamic nihilism: "being created from zero then destroyed by negative one, according to elementary school subtraction".

The Big Bang Model: A Critical Examination

Conceptual Flaws

The Big Bang model suggests a singular origin point with zero volume and infinite density, a concept that presents several theoretical inconsistencies:

1. Zero-Probability Origin: The notion of an initial singularity contradicts the principles of probability and determinism.

2. Singular Explosion: The model's reliance on a singular explosive event fails to account for continuous processes observed in nature.

Empirical Challenges

While the Big Bang model is supported by observations such as the cosmic microwave background (CMB) radiation and the redshift of distant galaxies, these phenomena can be interpreted differently within the framework of the Big Now.

The Big Now Model: A Reassessment

Conceptual Foundations

The Big Now rejects the idea of a singular origin, advocating for a continuous and interconnected cosmological framework based on atomic continuity and human cognition. This model aligns with several advanced mathematical theories:

1. Cantor's Diagonal Argument: This argument demonstrates the existence of multiple infinities, challenging the finite singularity proposed by the Big Bang.

2. Gödel's Mathematical Platonism: Gödel's perspective on mathematical truths existing independently of human knowledge supports the idea of a continuous, interconnected universe.

Theoretical Underpinnings

Quantum Mechanics

The equations of quantum mechanics, particularly those describing entanglement and superposition, align with the Big Now's emphasis on continuous processes and interconnectedness. Key examples include:

• Schrödinger's Equation:This fundamental equation describes how the quantum state of a physical system changes over time, emphasizing the continuous evolution of wave functions.

• Heisenberg Uncertainty Principle: This principle highlights the inherent uncertainty in measuring pairs of complementary properties, underscoring the interconnectedness of physical properties at the quantum level.

General Relativity

Einstein's equations of general relativity, which describe the curvature of spacetime, support the idea of a dynamic, interconnected universe without requiring a singular origin. Key examples include:

• Einstein Field Equations: These equations describe how matter and energy influence the curvature of spacetime, illustrating the interconnected nature of the universe.

• Friedmann Equations: These equations, derived from Einstein's field equations, govern the expansion of the universe and can be interpreted within the Big Now framework to suggest continuous processes rather than a singular explosive origin.

Humanitarian Perspective

The Big Now integrates a humanitarian perspective, emphasizing thermodynamic literacy and the interconnectedness of all surface immune systems on Earth. This approach highlights the importance of understanding the universe in a way that aligns with human cognition and the holistic functioning of ecosystems.

Empirical Support for The Big Now

1. Redefining CMB and Redshift: The cosmic microwave background radiation and redshift of distant galaxies can be reinterpreted within the Big Now framework as evidence of continuous processes rather than remnants of a singular explosion.

2. Atomic Continuity: Observations of atomic and subatomic interactions support the Big Now's emphasis on continuity and interconnectedness.

Implications for Cosmology

Scientific Inquiry

The Big Now model encourages interdisciplinary research that integrates cosmology with cognitive science, thermodynamics, and humanitarian efforts. This approach fosters a more comprehensive understanding of the universe and its origins.

Thermodynamic Literacy

Promoting thermodynamic literacy among all surface immune systems is crucial for addressing global challenges. By understanding the principles of thermodynamics, humanity can develop sustainable practices that align with the natural laws governing our solar-centric planet.

Conclusion

The Big Bang model, with its reliance on a singular explosive origin, presents several conceptual and empirical challenges. In contrast, the Big Now offers a consistent and holistic framework that aligns with advanced mathematical theories and emphasizes atomic continuity and interconnectedness. By integrating Cantor's diagonal argument, Gödel's mathematical Platonism, and equations from quantum mechanics and general relativity, the Big Now provides a robust alternative to the traditional cosmological model. Furthermore, the Big Now underscores the importance of thermodynamic literacy and humanitarian efforts in understanding and sustaining our interconnected universe.