Quantum Memory Matrix Theory Proposes Universe as Information Network

A new theory, the Quantum Memory Matrix (QMM), suggests that spacetime itself functions as a vast, interconnected network for storing information, potentially revolutionizing our understanding of the cosmos. Physicist Florian Neukart and his team champion this framework, which aims to resolve persistent paradoxes in theoretical physics, including the black hole information loss problem. The QMM theory posits that spacetime is not merely a passive backdrop but a dynamic quantum memory that records every fundamental interaction since the universe's beginning.

This stored information is believed to exist within discrete quantum cells at the Planck scale, influencing the universe's geometry. This concept of a geometry-information duality offers a novel perspective on gravity, black holes, and the universe's overall structure. A significant aspect of the QMM theory is its potential to explain phenomena such as dark matter and dark energy without the need for hypothetical undiscovered particles. The theory proposes that concentrations of "imprint entropy," which is information stored within spacetime, could replicate the gravitational effects attributed to dark matter. Further research suggests that imprint entropy could be responsible for the formation of large-scale structures in the universe, acting as a gravitational scaffold for ordinary matter.

Furthermore, the QMM theory suggests that the saturation of information within these spacetime cells could generate a residual energy that drives the universe's accelerated expansion, akin to dark energy. This provides a unified informational explanation for these cosmic enigmas. The theory also touches upon the cyclical nature of the universe, suggesting a finite number of expansion and contraction cycles, with the possibility of endless repetition determined by spacetime's informational capacity. Instead of collapsing into a singularity, the universe would undergo a "big bounce" upon reaching maximum capacity, initiating a new expansion cycle. This 'big bounce' replaces the concept of an absolute beginning, rather than an absolute end. These explanations align with observations that dark energy constitutes approximately 74% of the universe and dark matter about 22%.

Numerical simulations and tests conducted on quantum computers supporting the QMM theory have shown over 90% fidelity in recovering original states, indicating the physical implementability of its principles and potential advancements in quantum computing. The QMM framework presents the universe as an information-processing entity where events leave lasting imprints on reality. This perspective addresses the black hole information paradox by proposing information preservation within spacetime memory and suggests a fundamentally interconnected and dynamic universe. The validation of this paradigm-shifting theory and the enhancement of our cosmic comprehension are vital and ongoing. Research in the field of quantum memory and its potential connection to dark matter and dark energy is opening new horizons for understanding the cosmos.