In 2016, scientists
discovered the time crystals, solids with an oscillating internal structure that simply repeats itself in very time rather than in the space. Now, they have found a new one, in
a regular crystal that can be easily made at home in one of those
grow-your-own-crystal the toys.
As reported in two studies
published in Physical Review Letters and Physical Review B, researchers have
identified the typical behavior of a discrete time crystal (DTC) in
mono-ammonium phosphate. This discovery complicates the theory behind time
crystals, as researchers have generally believed that these objects require a
certain "internal disorder" to be able to act as time crystals.
The team had grown crystals
for a different experiment but were curious to see if they could observe the
expected DTC signal in them. They used nuclear magnetic resonance and were
surprised to discover the signature as quickly as they did.
"Our crystal
measurements looked quite striking right off the bat," principal
investigator for the two new studies Professor Sean Barrett, from Yale
University, said in a statement. "Our work suggests that the signature of
a DTC could be found, in principle, by looking in a children's crystal growing
kit."
Time crystals have been
likened to weird jiggling Jell-O. You start shaking it, but the gelatin
oscillates with a frequency that doesn’t correspond to your movements. This is
what happens with time crystals. No matter what your initial push might have
been, the time crystal assumes a specific frequency. So even if your pulses are
imperfect, the time crystal will oscillate with a clockwork tick.
How such structures come to
be is unclear and the new research challenges many of the expectations and
ideas put forward over the last two years. "We realized that just finding
the DTC signature didn't necessarily prove that the system had a quantum memory
of how it came to be," said Yale graduate student Robert Blum, a co-author
of the studies.
"This spurred us to try
a time crystal 'echo,' which revealed the hidden coherence, or quantum order,
within the system," lead author Jared Rovny, also a Yale graduate student,
explained.
Time crystals could
potentially improve well-established technologies like atomic clocks,
magnetometers, and even the gyroscopes used in mobile phones to determine their
orientation. They might even play an important role in emergent quantum
technologies, an area of research that will likely see increased investment
over the next few years.
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