Scientists at Leiden University in the Netherlands have proposed a groundbreaking theory called "Quantum Memory Matrix" (QMM). This theory could potentially resolve the long-standing information paradox of black holes and shed light on the nature of dark matter.
The QMM functions as a dynamic quantum information reservoir, where quantum imprints encode data about the quantum states and interactions within black holes. This suggests that information lost to black holes is preserved in the "memory" of the universe, rather than disappearing entirely.
This theory also offers a potential explanation for the mystery of dark matter. Research indicates that the initial black holes formed in the early universe may constitute a significant portion of dark matter, as their quantum correlations could be linked to the observed gravitational effects.
To test this theory, scientists are planning to use gravitational wave detectors like LISA, BBO, and ET. These detectors are expected to reveal the characteristic spectrum of gravitational waves generated during the collision of primordial black holes, which would support the QMM theory and its connection to dark matter.
In essence, the "Quantum Memory Matrix" theory opens up new horizons in understanding the fundamental aspects of the universe, offering a potential solution to one of the most complex paradoxes in physics and a possible explanation for dark matter.