Physicists Unlock Quantum Immortality With Revolutionary Time Crystal

Physicists Unlock Quantum Immortality With Revolutionary Time Crystal

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Abstract Time Crystal Concept

Scientists have made a significant advancement in the field of quantum physics by producing a time crystal with a lifespan millions of times longer than previously achieved. This discovery validates the theoretical prediction of time crystals made by Nobel laureate Frank Wilczek in 2012, demonstrating periodic behavior in a system without periodic external influence.

Researchers have successfully extended the lifespan of time crystals, confirming a theoretical concept proposed by Frank Wilczek. This marks a significant step forward in quantum physics.

A team from TU Dortmund University recently succeeded in producing a highly durable time crystal that lived millions of times longer than could be shown in previous experiments. By doing so, they have corroborated an extremely interesting phenomenon that Nobel Prize laureate Frank Wilczek postulated around ten years ago and which had already found its way into science fiction movies. The results have now been published in Nature Physics.

Groundbreaking Achievement in Time Crystal Research

Crystals or, to be more precise, crystals in space, are periodic arrangements of atoms over large length scales. This arrangement gives crystals their fascinating appearance, with smooth facets like in gemstones.

As physics often treats space and time on one and the same level, for example in special relativity, Frank Wilczek, a physicist at the Massachusetts Institute of Technology (MIT) and winner of the Nobel Prize in Physics, postulated in 2012 that, in addition to crystals in space, there must also be crystals in time. For this to be the case, he said, one of their physical properties would have to spontaneously begin to change periodically in time, even though the system does not experience corresponding periodic interference.

Time Crystal Looks Like Flame

What looks like a flame is the measurement of the new time crystal: Each point corresponds to an experimental value, resulting in different views of the periodic dynamics of the nuclear spin polarization of the time crystal. Credit: Alex Greilich/TU Dortmund University

Understanding Time Crystals

That such time crystals could be possible was the subject of controversial scientific debate for several years – but quick to arrive in the movie theater: For example, a time crystal played a central role in Marvel Studios’ movie Avengers: Endgame (2019). From 2017 onwards, scientists have indeed succeeded on a handful of occasions in demonstrating a potential time crystal.

Alex Greilich Crop

Dr. Alex Greilich works at the Condensed Matter research focus of the Department of Physics at TU Dortmund University. Credit: TU Dortmund University

However, these were systems that – unlike Wilczek’s original idea – are subjected to a temporal excitation with a specific periodicity, but then react with another period twice as long. A crystal that behaves periodically in time, although excitation is time-independent, i.e. constant, was only demonstrated in 2022 in a Bose-Einstein condensate. However, the crystal lived for just a few milliseconds.

A Leap in Time Crystal Longevity

The Dortmund physicists led by Dr. Alex Greilich have now designed a special crystal made of indium gallium arsenide, in which the nuclear spins act as a reservoir for the time crystal. The crystal is continuously illuminated so that a nuclear spin polarization forms through interaction with electron spins. And it is precisely this nuclear spin polarization that then spontaneously generates oscillations, equivalent to a time crystal.

The status of the experiments at the present time is that the crystal’s lifetime is at least 40 minutes, which is ten million times longer than has been demonstrated to date, and it could potentially live far longer.

It is possible to vary the crystal’s period over wide ranges by systematically changing the experimental conditions. However, it is also possible to move into areas where the crystal “melts,” i.e. loses its periodicity. These areas are also interesting, as chaotic behavior, which can be maintained over long periods of time, is then manifested. This is the first time that scientists have been able to use theoretical tools to analyze the chaotic behavior of such systems.

Reference: “Robust continuous time crystal in an electron–nuclear spin system” by A. Greilich, N. E. Kopteva, A. N. Kamenskii, P. S. Sokolov, V. L. Korenev and M. Bayer, 24 January 2024, Nature Physics.
DOI: 10.1038/s41567-023-02351-6



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