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Review of frequency comb spectroscopy

8 March 2019 | News

In recent years, powerful and potentially game-changing new tools for spectroscopy have emerged, based on mode-locked ultrafast lasers and their broad combs of evenly spaced sharp spectral lines. A review article in Nature Photonics by Nathalie Picqué and Theodor W. Hänsch discusses developments and prospects in the emerging and quickly advancing field of atomic and molecular broadband spectroscopy with frequency combs.

A frequency comb (see figure) is a spectrum of phase-coherent sharp laser lines that are evenly spaced. Such combs based on femtosecond mode-locked lasers, as pioneered at the Max-Planck Institute of Quantum Optics in the 1990s, have revolutionised measurements of frequency and time. In frequency metrology, a laser comb acts as a ruler in frequency space, that conveniently links microwave and optical frequencies, and/or measures a large separation between two optical frequencies. In the past decade, frequency combs have found new applications. One of these is frequency comb spectroscopy: spectroscopy where the comb is used to directly excite or interrogate a sample. Molecular spectroscopy with frequency combs offers particularly intriguing opportunities, since complex spectra can be interrogated simultaneously by a large number of comb lines over a broad spectral range.

In the review article, Nathalie Picqué and Theodor W. Hänsch, from the Laser Spectroscopy Division of the Max Planck Institute of Quantum Optics and the Faculty of Physics of the Ludwig Maximilian University of Munich, present a summary of developments in the hot field of frequency comb spectroscopy and its emerging applications.

Frequency combs bring a set of new tools to spectroscopy in all phases of matter. The past decade has witnessed remarkable progress in laser frequency comb generators dedicated to broadband spectroscopy, especially in the molecular-fingerprint mid-infrared (2–20 μm) region and the ultraviolet range (<400 nm). Such synthesisers harness modern tools of laser physics and non-linear optics technology: mode-locked lasers, non-linear frequency conversion, microresonators, electro-optic modulators, semi-conductor lasers etc. Existing spectrometers and spectrometric techniques have been adapted and improved to make the most of such sources, while entirely new comb-enabled approaches and instruments have been explored.

The new features enabled by frequency comb spectroscopy hold much promise for a vast number of applications ranging from fundamental physics to optical sensing. For instance, chip-scale frequency comb spectrometers may lead to integrated devices for chemical and biomedical sensing in real time.

 

 

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