Described in the March 25 issue of Nature, the NIST-led work is the first to compare three clocks based on different atoms, and the first to link the most advanced atomic clocks in different locations over the air. These atomic clock comparisons place the scientific community one step closer to meeting the guidelines for redefinition of the second. “These comparisons are really defining the state of the art for both fiber-based and free-space measurements — they are all close to 10 times more accurate than any clock comparisons using different atoms performed so far,” NIST physicist David Hume said. The new measurements were challenging because the three types of atoms involved “tick” at vastly different frequencies, because all the many network components had to operate with extreme accuracy, and because the wireless link required cutting-edge laser technology and design. The study compared the aluminum-ion clock and ytterbium lattice clock, located in different laboratories at NIST Boulder, with the strontium lattice clock located 1.5 kilometers away at JILA, a joint institute of NIST and the University of Colorado Boulder. The team’s measurements were so accurate that uncertainties were only 6 to 8 parts in 1018 — that is, errors never exceeded 0.000000000000000008 — for both fiber and wireless links. NIST researchers previously described in detail how they transferred time signals over the air link between two of the clocks, the NIST ytterbium and JILA strontium clocks, and found the process worked as well as the fiber-based method and 1,000 times more precisely than conventional wireless transfer schemes. This work shows how the best atomic clocks might be synchronized across remote sites on Earth and, as time signals are transferred over longer distances, even between spacecraft. The key to the air link was the use of optical frequency combs, which enable accurate comparisons of widely different frequencies. NIST researchers developed two-way transfer methods to precisely compare optical clocks over the air, even in conditions of atmospheric turbulence and laboratory vibrations. The comb-based signal transfer technique had been demonstrated previously, but the latest work was the first to compare state-of-the-art atomic clocks. Since 1967, the second has been defined based on the cesium atom, which ticks at a microwave frequency. The atomic clocks used in the new comparisons tick at much higher optical frequencies, which divide time into smaller units and thus offer greater precision. Comparisons are crucial to the international community’s selection of one or more atoms as the next time standard. The new NIST results reported in Nature also set other important records. Frequency is the most accurately measured single quantity in science. The NIST team measured frequency ratios, the quantitative relationships between the frequencies of the atoms as measured in three pairs (ytterbium-strontium, ytterbium-aluminum, aluminum-strontium). The results are the three most accurate measurements ever made of natural constants. Frequency ratios are considered constants and are used in some international standards and tests of fundamental physics theories. Frequency ratios offer an important advantage as a metric for evaluating optical atomic clocks. A direct measurement of an optical clock frequency in the usual units of hertz (one cycle per second) is limited by the accuracy of the current international standard, the cesium microwave clock. Frequency ratios overcome this limitation because they are not expressed in any units. Frequency ratios are usually measured over long distances by use of fiber networks, which are few and far between, or in some cases with microwave data transferred over satellite links, which tend to be unstable. Guidelines for redefinition of the second recommend the demonstration and verification of multiple frequency ratio measurements with uncertainties approaching the best optical clock performance. All three types of clocks in the new study offer superlative performance now and promise further improvements. NIST’s ytterbium clocks, for example, represent the natural frequency of the atoms (a value known as systematic uncertainty) to within a possible error of just 1.4 parts in 1018 — about one billionth of a billionth. NIST’s new frequency ratio measurements, while record-setting, are not quite that good yet. But the research team is working on improving measurement stability and clock performance, Hume said. Beyond their role in the next generation of international standards, optical atomic clocks can be used as sensitive probes for new physics, such as the “dark matter” believed to constitute most of the stuff in the universe. Technological applications for optical clocks include improved timing and navigation systems and measuring Earth’s gravitational shape (geodesy). Reference: “Frequency ratio measurements at 18-digit accuracy using an optical clock network” by Boulder Atomic Clock Optical Network (BACON) Collaboration, 24 March 2021, Nature.DOI: 10.1038/s41586-021-03253-4 This work was supported in part by the Defense Advanced Research Projects Agency, the Air Force Office for Scientific Research, the National Science Foundation, the Office of Naval Research, NASA Fundamental Physics, and the Department of Energy.