Scientists create a clock so accurate it won't lose time for 40 million years
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Jackson RyanFormer Science Editor
Jackson Ryan was CNET's science editor, and a multiple award-winning one at that. Earlier, he'd been a scientist, but he realized he wasn't very happy sitting at a lab bench all day. Science writing, he realized, was the best job in the world -- it let him tell stories about space, the planet, climate change and the people working at the frontiers of human knowledge. He also owns a lot of ugly Christmas sweaters.
The Cryogenic Sapphire Oscillator is one of the most precise clocks ever invented -- and it's not just keeping time, it's keeping Australia safe.
Researchers at the Institute for Photonics and Advanced Sensing (IPAS) in Adelaide, Australia in conjunction with Cryoclock, have, for the past 20 years been working on developing the Oscillator which they have dubbed the "Sapphire Clock."
It is 1,000 times more precise than any other commercial system currently available and ticks 10 billion times per second. The "cryogenic" in the device's real name comes from the 1,200-carat sapphire crystal that needs to be cooled to minus 267 degrees Celsius (around 449 degrees Fahrenheit) -- only a few degrees above absolute zero.
The idea to harness the amazing properties of sapphire came from Andre Luiten, director of IPAS, during his PhD project before moving to Adelaide in 2013.
Accuracy in timing is an important aspect of electronics systems we use every day, such as GPS. However, the chief application of the Sapphire Clock would be to upgrade the sensitivity of radar signalling in JORN, an over-the-horizon radar network that acts as an early warning system in Australia's defence capabilities.
You can watch a video on the achievement below:
The radar network plays a role in Australia's ability to detect foreign threats by air or sea by broadcasting a signal that is reflected of a foreign object and then detected by a receiver back on land in Australia. The more "pure" that signal is, the better capacity the radar network has to detect smaller, slower objects at greater distance.
"The sensitivity to detect objects at great distances depends on the purity of the reference clock frequencies. Our Sapphire Clock would allow JORN to generate signals that are 1000 times purer than its current technology," said Luiten.
Beyond improving JORN's capabilities, Luiten also sees the Sapphire Clock providing other uses in the future. "In the longer term we see other applications - in civilian radar at airports for example, or in providing the master clock for quantum computers, or in providing the timing for 5G telecommunications base stations," Luiten told CNET.
It's an impressive scientific achievement and one that saw the research team take out the 2018 Defence Science and Technology Prize for Outstanding Science in Safeguarding Australia award at the Australian Museum Eureka Prizes on Aug. 29. The annual awards event rewards scientific excellence across research and innovation, in addition to science engagement and education.
More impressive? The clock is one of eight currently built and operational. Two will be shipped out to JORN, but two remain in the University. A new "next generation" unit, half the size of the original, is now the focus of more experimentation.
It's not the first time a clock has been developed with such unbelievable precision. Horologists have been working out ways to make our time-keeping ever more accurate for decades. In 2014, the strontium clock was created, able to keep time without losing a second for some 5 billion years. Newer iterations on the strontium clock can keep time for 90 billion years.
With all these huge numbers... I'm setting my watch to stunned.
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