The QMM framework provides a potential solution to the black hole information paradox, suggesting that information falling into black holes is stored in spacetime's memory and not lost, aligning with quantum theory.

Recent experiments using quantum computers have tested aspects of the QMM, successfully retrieving quantum states with over 90% accuracy, demonstrating the model's practical potential for quantum error correction and understanding spacetime.

All fundamental forces—gravity, electromagnetism, and nuclear forces—leave traces in spacetime, supporting the broader principle of geometry-information duality, which influences the universe's structure and evolution.

This framework introduces the principle of geometry-information duality, which states that spacetime's shape and behavior are influenced not only by mass and energy but also by the distribution of quantum information and entanglement, potentially explaining phenomena like dark matter and dark energy.

By integrating information theory with cosmology, the QMM proposes that the universe functions as both a memory bank and a quantum computer, offering new insights into dark matter, dark energy, and the universe's cyclic nature.

QMM suggests that spacetime is composed of tiny cells that store quantum imprints of all interactions, meaning the universe not only evolves but also retains a memory of past events.

A groundbreaking theoretical framework called the quantum memory matrix (QMM) suggests that information, rather than matter or energy, is the fundamental building block of reality, with spacetime being discrete and serving as a cosmic memory bank.

This perspective explains dark matter as clusters of imprints in spacetime that drive galaxy motions without requiring new particles, and dark energy as residual energy from saturated spacetime cells that fuels cosmic acceleration.

The QMM predicts a cyclic universe, where each phase of expansion is followed by contraction and a bounce, driven by the saturation of spacetime's informational capacity, leading to multiple cosmic cycles over billions of years.

Considering these cycles, the universe's total age could be around 62 billion years, much older than the 13.8 billion-year estimate based solely on expansion, due to repeated phases of cosmic rebirth.

Experimental tests on quantum computers have demonstrated the effectiveness of the imprint operator, which can retrieve quantum states with high accuracy, hinting at practical applications and deeper insights into the universe's workings.