Researchers from the US National Institute of Standards and Technology (NIST) and California Institute of Technology (Caltech) have demonstrated a new design for an atomic clock based on a chip-scale frequency comb.
The so-called microcomb clock is claimed to be the first demonstration of all-optical control of the microcomb, and its accurate conversion of optical frequencies to lower microwave frequencies.
According to NIST, the new clock architecture might eventually be used to make portable tools for calibrating frequencies of advanced telecommunications systems or provide microwave signals to boost stability and resolution in radar, navigation and scientific instruments. The technology also has potential to combine good timekeeping precision with very small size. Furthermore, the comb clock might be a component of future ‘NIST on a chip’ technologies offering multiple measurement methods and standards in a portable form.
‘The microcomb clock is one way we might get precision frequency metrology tools out of the lab and into real-world settings,’ NIST physicist Scott Diddams said in a statement.
Frequency combs produce precisely defined colours, or frequencies, of light that are evenly spaced throughout the comb’s range. The original combs required relatively large lasers that produced rapid, extremely short pulses of light, but more recently NIST and other laboratories have developed much smaller microcombs.
A microcomb generates its set of frequencies from light that gets trapped in the periphery of a tiny silica glass disk, looping around the perimeter. NIST has an on-going collaboration in this area with Caltech researchers, who made the 2mm wide silica disk that generates the frequency comb for the new clock.
The new microcomb clock uses a laser to excite the Caltech disk to generate a frequency comb, broadens the spectrum using nonlinear fibre, and stabilizes two comb teeth – or individual frequencies – to energy transitions in rubidium atoms that ‘tick’ at optical frequencies. The comb converts these optical frequency ticks to the microwave domain.
Thanks to the gear-like properties of the disk and the comb, the output is also 100 times more stable than the intrinsic ticking of the rubidium atoms.
Diddams said: ‘A simple analogy is that of a mechanical clock: The rubidium atoms provide stable oscillations – a pendulum – and the microcomb is like a set of gears that synthesises optical and microwave frequencies.’
The centre of the comb spectrum is locked to an infrared laser operating at 1,560nm, a wavelength used in telecommunications.
NIST researchers have not yet systematically analysed the microcomb clock’s precision. The prototype uses a tabletop-sized rubidium reference. The scientists expect to reduce the instrument size by switching to a miniature container of atoms like that used in NIST’s original chip-scale atomic clock. Scientists also hope to find a more stable atomic reference.
The microcomb chip was made by use of conventional semiconductor fabrication techniques and could be mass-produced and integrated with other chip-scale components such as lasers and atomic references. NIST researchers expect that, with further research, the microcomb clock architecture can achieve substantially better performance in the future.