Quantum physics has always challenged our understanding of reality, but a new breakthrough further pushes the limits. Researchers at Washington University in St. Louis have has created a new phase of material Known as Time Quasicristal, an advanced version of Time Crystals, which was discovered for the first time in 2016.
These materials almost seem to challenge the laws of physics, remaining in perpetual motion without spending energy. The first iteration of this discovery could have enormous implications for quantum computer science, the precision stopwatch and advanced detection technologies, with quasi-cristals of time that should go even further.
Time crystals work similarly to conventional crystals such as diamonds or quartz, which have atomic structures that are repeated in space. The difference is that time crystals repeat reasons in time. This means that they oscillate at constant frequencies without requiring an external energy source.
They theoretically never stop “ticking”, which makes it a potential change of play for quantum storage and the chronometer. The team at the University of Washington pushed a little further by developing an even more complex quasi-cristal.
Unlike regular time crystals that oscillate in a predictable model, the quasi-cristals of time vibrate simultaneously at several frequencies, creating a richer and more complex structure. To achieve this, researchers have integrated atomic gaps into diamonds and stimulated them using microwave pulses.
The potential applications of the time that quasi-cristals are exciting, especially in quantum calculation. One of the largest challenges in quantum systems is to maintain consistency, as quantum information tends to deteriorate over time due to external interference.
Temporal crystals could provide a long -term quantum memory, similar to the RAM function in conventional computers, but without the same energy limitations. Scientists also believe that quasi-cristals could revolutionize the precision stopwatch, offering an alternative to oscillators based on quartz, which gradually lose precision.
However This discovery is still at its beginningsIt confirms fundamental quantum theories while opening the door to new possibilities in IT and detection technology.
If researchers can find a way to fully control and evolve these quasi-cristals, they could play a central role in new generation quantum technologies.