What question did this study set out to answer?

The study aims to extend Thermal Relativity by interpreting black holes through thermodynamics instead of geometry.

February 11, 2026Open Access

Thermal Relativity (TR): Black Holes as Thermal Phase Structures and Gravitational Waves as Thermal-Time Pulses

Key Points

The study aims to extend Thermal Relativity by interpreting black holes through thermodynamics instead of geometry.
Applied a first-principles Boltzmann solver
Analyzed thermal energy forcing
Examined black hole horizons as pressure-defined boundaries
Studied gravitational wave emission as thermal phenomena
Black holes characterized as thermodynamic phase structures
Demonstrated saturation effect resulting in local time termination
Provided new interpretations of gravitational wave emissions
Reproduced known strong-field observables with a non-geometric framework

Abstract

This paper presents a strong-field extension of Thermal Relativity (TR), interpreting black holes as thermodynamic phase structures rather than geometric singularities. Using results from a first-principles, certified Boltzmann solver, the work shows that extreme free thermal energy forcing drives the lattice ordering response to saturation, terminating measurable time locally. Black hole horizons are reinterpreted as pressure-defined activation boundaries, while evaporation and gravitational waves emerge as thermal phase conversion and thermal-time pulses, respectively. The framework reproduces known strong-field observables while providing a non-geometric, physically grounded interpretation of horizons, evaporation, and gravitational wave emission.

Read Full Paperexternally

Connected Papers

Building similarity graph...

Analyzing shared references across papers

Discussion

References and Citations

Add This Paper to Your Research Feed

Any time a new paper drops it will be there.