Physicist points out physical evidence of a simulated universe with new law of infodynamics

Physicist Melvin Vopson, from Universidade to Portsmouth, in Reino Unido, proposes that the universe functions as an advanced computer simulation. Ele bases this idea on a physical law he developed called the second law of infodynamics. Essa law observes that information entropy in systems tends to decrease or remain constant, contrary to what occurs with traditional thermodynamic entropy.

The second law of thermodynamics states that disorder increases in isolated systems over time. Exemplos include the gradual cooling of hot objects until they reach equilibrium with their surroundings. However, Vopson identified opposite behavior in information systems, where information entropy is minimized, suggesting data optimization and compression processes.

This characteristic resembles the functioning of computers and complex digital simulations. A simulated universe would require efficient mechanisms to reduce storage and processing requirements. The researcher argues that patterns observed in nature indicate exactly this type of optimization.

New physical law under analysis

The second law of infodynamics applies to different fields. In digital systems, information is organized in a way that minimizes redundancies. At the atomic level, mathematical symmetries arise as states of low informational entropy.

In biology, the study of genomes reveals similar patterns. Vopson analyzed mutations in the SARS-CoV-2 virus and observed that the entropy of genetic information decreases over time. Esse process points in a deterministic direction in mutations, prioritizing data efficiency over pure randomness.

Symmetry predominates in natural structures, from crystals to biological molecules. Highly symmetric Estados correspond to the least amount of information required for description. Nature seems to favor this configuration to optimize data storage.

Applications in viral genomes

Researchers examined real genetic sequences of SARS-CoV-2 throughout its evolution. Mutations are not distributed in a purely random way, according to the classic Darwinian model. Instead, they follow a trend towards a reduction in informational entropy, reaching a minimum balance.

This dynamic suggests a self-optimization mechanism in the genetic code. The virus adjusts its information for greater computational efficiency. Vopson and collaborators highlight that such behavior reinforces the idea of ​​the universe as a programmed system.

Symmetries and cosmic efficiency

The prevalence of symmetries in nature is explained from this perspective. Flocos of snow, molecular structures and cosmological patterns exhibit high symmetry. Esses states minimize the entropy of the information involved.

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The vast universe requires extreme data compression for viable simulation. The minimization observed at multiple levels supports the hypothesis. Vopson asserts that these patterns occur in digital data, biology, atomic physics, and cosmology.

The law applies universally and appears as a cosmological necessity. Ela balances the increase in thermodynamic entropy with a reduction in informational entropy. Essa compensation allows expansion of the universe without violating fundamental principles.

Ongoing scientific debate

The simulation hypothesis remains speculative among physicists and philosophers. Ela gained attention after formulations like the argument for Nick Bostrom. Figuras from technology also discuss the possibility.

Vopson presents empirical evidence based on his law. Estudos in viral mutations and mathematical symmetries provide observational support. Ainda therefore, the scientific community demands more independent testing and verification.

The theory did not reach consensus. Ela coexists with traditional views of physics. Pesquisas Futures may explore specific predictions of the law to validate or refute its implications.

Implications for physics and biology

The second law of infodynamics impacts different areas. In genetics, mutations driven by informational minimization alter evolutionary understanding. In cosmology, it explains patterns observed on a large scale.

The researcher suggests that information has mass and constitutes a fundamental state. Isso connects quantum physics, thermodynamics and information theory. Avanços may emerge in gene therapies and computing.

The idea challenges established views. Ela proposes that natural regularities derive from computational optimization. Current Observações align with this vision, although they require rigorous verification.