Physics Paper Redefines Black Hole Singularities as Spacetime Breakdown

A groundbreaking physics paper published in February 2026 challenges the century-old understanding of black hole singularities, proposing a revolutionary alternative to the concept of infinite curvature at these cosmic centers. The research, conducted by independent theoretical physicist Michael Aaron Cody and published in the prestigious European Physical Journal Plus by Springer Nature, argues that singularities don't represent physical infinities but rather indicate where our mathematical description of spacetime breaks down completely. This work introduces a mechanical failure condition for spacetime, drawing parallels to how materials fail under extreme stress or how fluid models become inadequate at microscopic scales.

Using established equations from general relativity, the paper identifies a clear threshold where the continuum description of spacetime ceases to apply, offering a physically grounded framework that eliminates the need for infinite quantities. Crucially, this new explanation doesn't alter any tested predictions of general relativity outside the event horizon, meaning observable black hole behavior remains unchanged while providing a more coherent understanding of what happens at their cores. The research, which was independently conducted and self-funded, represents a significant step toward resolving one of physics' most persistent paradoxes and is available through the published paper and preprint links for further examination.

The published paper can be accessed through the European Physical Journal Plus, while a preprint version offers free access to this groundbreaking research. Michael Aaron Cody brings over two decades of self-directed study and ten years of university work to this investigation, with his work consistently focusing on first-principles approaches to long-standing physics problems across multiple peer-reviewed journals and research outlets.