Sound creates light

The PTB physicists Harald Schnatz and Gesine Grosche are internationally leading experts in the precise measurement and transmission of frequencies via optical fibers. They use the optical frequency of the light, with some 195 · 1012 cycles per second, as the information. A first application of this new method was the remote measurement, conducted last year, of the so-called optical clock transition in a magnesium clock at the Leibniz University of Hannover. The scientists determined the characteristic frequency with which very cold magnesium atoms can be excited to a particular long-lived state, by a measurement from PTB via 73 km optical fiber. It is important to measure such frequencies accurately as they can in principle be used to "generate" seconds. "For such measurements, there are femtosecond frequency comb generators at both ends, which produce a fixed phase relationship between the transmitted light and the frequency standards on site", explains Harald Schnatz. The frequency standards on site are the new magnesium clock in Hanover and an optical clock at PTB. The different frequencies of the two are synchronized with the aid of femtosecond frequency comb generators, which can be compared to a gear mechanism. Schnatz adds: "At first we were astonished how well this complete system works."

Now the researchers wanted to bridge larger distances and build a connection for joint experiments to the Max-Planck Institute for Quantum Optics (MPQ) in Garching - a link of 900 km fiber, which attenuates the light by the almost inconceivable factor of 1020 if it is not amplified. Moreover, the fiber has to be passed through twice, because it is part of a huge interferometer; this is how the optical length of the entire link, which otherwise varies due to temperature fluctuations, is stabilized. Here, conventional amplification techniques reach their limits. "Our PhD student, Osama Terra, hit on the brilliant idea of using the Brillouin amplification in the fiber itself", says Gesine Grosche: "This gives us several advantages at the same time: First, even very weak signals are still amplified; the signal power is multiplied by a factor of up to one million. Thus, we need considerably fewer amplifier stations. Moreover, it is possible to selectively amplify very narrow-band light signals." This is very advantageous for the testing of the narrow-band clock transitions of optical clocks.

The group immediately tested this concept on a deployed underground fiber link: in cooperation with the "Deutsches Forschungsnetz" (DFN) (German National Research and Education Network) and the GasLINE company, which together operate a German-wide fiber network. With only one intermediate amplification station, the ultra-stable frequency was transmitted over a record 480 km long fiber link - with a relative transmission uncertainty of only 2 parts in 1018, which is equivalent to a deviation of about one second in 16 billion years. As a result, even a connection with the French partner institute of PTB in Paris now looks realistic - with a vision of working together on the best optical clocks in the future.

At the technical conference "European Frequency and Time Forum" (EFTF), the results also received recognition: Osama Terra won the Student Award of the EFTF for his contribution in the field of "Timekeeping, Time and Frequency Transfer". The results have been submitted for publication and are available on the "arXiv" preprint server. Currently, the three researchers and their colleagues at MPQ Garching are continuing to work frenetically on establishing a connection between their institutes. They want to deliver the ultra-stable reference frequency of PTB to the laboratory of the working group of Professor Theodor Hänsch, where elementary properties of the hydrogen atom are measured spectroscopically with very high accuracy.

For the future, Gesine Grosche and Harald Schnatz are seeking to strengthen their team: with Post-docs and doctoral candidates who are keen to meet the challenges of working in this very active area. Interested parties should contact gesine.grosche(at)ptb.de by e-mail. Prospective doctoral candidates can then apply online - until mid July - with the keyword "Faserlink" in the current HALOSTAR program (www.halostar.de).

Contact:
Dr. Gesine Grosche, PTB Working Group 4.31 Unit of Length,
Tel.: +49 531 592-4318,
e-mail: gesine.grosche@ptb.de

Original publications:
O. Terra, G. Grosche, H. Schnatz: Brillouin amplification in phase coherent transfer of optical frequencies over 480 km fiber. arXiv:1005.3925v1. arxiv.org/abs/1005.3925
 
Grosche, G; Terra, O; Predehl, K; Holzwarth, R; Lipphardt, B; Vogt, F; Sterr, U; Schnatz, H.: Optical frequency transfer via 146 km fiber link with 10-19 relative accuracy. Optics Letters, Vol. 34 Issue 15, pp. 2270-2272 (2009)