The rotating refrigerator at Aalto University. Credit: Aalto University / Mikko Raskinen
For the first time ever, scientists have witnessed the interaction of a new phase of matter known as “time crystals”.
The discovery, published in Natural materials, can lead to applications in quantum information processing, because time crystals automatically remain intact – coherent – in changing conditions. Protecting coherence is the main difficulty that hinders the development of powerful quantum computers.
Dr Samuli Autti, lead author of Lancaster University, said: “Monitoring the interaction of two time crystals is an important achievement. Before having observed two time crystals in the same system, let alone seeing interaction.
“Controlled interactions are the number one item on the wish list of anyone looking to use a time crystal for practical applications, such as processing quantum information.”
Time crystals are different from a standard crystal – such as metals or rocks – which consists of atoms arranged in a regularly repeating pattern in space.
First theoretically identified in 2012 by Nobel Prize winner Frank Wilczek and in 2016, time crystals exhibit the bizarre property of being in constant, repetitive motion in time despite no external input. Their atoms oscillate, spin, or move first in one direction, and then the other.
An international team of researchers from Lancaster, Yale, Royal Holloway London, and Aalto University in Helsinki observed time crystals using Helium-3, which is a rare isotope of helium with one missing neutron. The experiment was conducted at Aalto University.
They cool excess helium-3 to within tens of thousands of degrees of absolute zero (0.0001K or -273.15 ° C). The researchers then made two time crystals within the abundance, and let them touch.
The scientists saw the two time crystals interacting and exchanging existing particles flowing from one nucleus crystal to another, and back – a phenomenon known as the Josephson effect.
Time crystals have great potential for practical applications. They could be used to improve current atomic clock technology – complex times that hold the most accurate time we can possibly reach. They could also improve technology such as gyroscopes, and systems that rely on atomic clocks, such as GPS.
Time crystals can keep secret for coherence in quantity processing
AC Josephson effect between two abundant time crystals, Natural materials (2020). DOI: 10.1038 / s41563-020-0780-y, www.nature.com/articles/s41563-020-0780-y
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Citation: First Observation of Time Crystals (August 17, 2020) Retrieved August 17, 2020 from https://phys.org/news/2020-08-crystals-interacting.html
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