Time-Shift Breakthrough: Scientists Unveil Revolutionary Clock

• China’s optical clock: 1 sec shift every 7 billion years.
• Breakthrough for global optical clock network and physics research.
• Applications in secure communication, satellites, and defense.

In a groundbreaking achievement, scientists in China have unveiled an optical clock with the astounding capability to lose or gain just one second every 7 billion years. This technological leap positions China as the world’s second country, following the University of Colorado in Boulder, to achieve such unparalleled precision in timekeeping.

Led by physicist Pan Jianwei, the research team documented their accomplishment in the peer-reviewed journal Metrologia. The optical clock not only challenges conventional notions of time but also lays the foundation for the establishment of a global optical clock network. This network, when realized, could usher in new opportunities for testing fundamental physics theories, detecting gravitational waves, and searching for elusive dark matter.

Despite the University of Colorado’s strontium-based optical clock retaining a slight edge in accuracy and stability, China’s achievement marks a significant stride in the quest for the most precise timekeeping technology. Competitors in the race include institutions such as the University of Tokyo, the Institute of Physical and Chemical Research in Japan, and the National Metrology Institute of Germany.

The potential applications of optical clocks extend beyond the realm of pure scientific curiosity. They hold promise for enhancing the precision of global navigation satellite systems, establishing highly secure communication networks through quantum key distribution, and contributing to the synchronization and efficiency of power grids. Moreover, the technology may play a pivotal role in national defense and security.

The current definition of a second relies on microwave fountain clocks, which release cesium atoms and track their motion to achieve precise time measurements. However, the limitations of microwave clocks have spurred the development of optical clocks, utilizing laser light to drive electronic transitions and achieving performance two orders of magnitude better than their microwave counterparts.

For optical clocks to replace microwave clocks in the future definition of time, at least three laboratories worldwide must possess an optical clock with stability below 5 quintillionths and uncertainty below 2 quintillionths. This remarkable Chinese achievement brings us one step closer to a potential paradigm shift in the way we perceive and measure time.

Also Read

Stellantis adopts ChatGPT for Peugeot cars’ driver communication

Peugeot adopts ChatGPT for in-car voice assistance. Integration covers all Peugeot vehicles....