Most powerful dual-comb spectrometer developed
Two trains of laser pulses with slightly different spacing originate from a thin-disk laser gain medium in the center of the picture. The work was recently published in Nature Communications.
HSU/Eric Schambroom
Scientists from Hamburg and Munich developed the world’s most powerful dual-comb spectrometer that paves the way for many applications in atmospheric science and biomedical diagnostics, such as early cancer detection. The work has recently been published in Nature Communications.
The core part of the system is a special type of laser-gain medium, a thin-disk, and a unique configuration of the mirrors surrounding this medium, a laser resonator (shown in the illustration). “The key of our dual comb laser source lies in its simplicity”, team leader Oleg Pronin explains. “Instead of using two separate lasers, actively stabilizing and locking them to each other, our two laser outputs originate from the same laser resonator, leading to an excellent intrinsic mutual stability.” The dual-output laser yields one order of magnitude higher power than ever before. This paves the way for many applications in atmospheric science and biomedical diagnostics, such as early cancer detection. Fundamental research applications such as precise measurements of the atomic lines in uncovered spectral ranges and nuclear clocks, the most precise clocks in our universe, come into reach thanks to this novel spectrometer.
The dual-comb spectrometer converts extremely fast electric field oscillations (10¹⁵ oscillations per second) of light into radiofrequency range (10⁶ oscillations per second), where the signal can be detected in real-time with modern electronics. The process is realized with two trains of laser pulses with slightly different spacing. It offers high sensitivity and resolution with fast acquisition times in the millisecond time scale. Megawatt level peak powers pave the way toward high-resolution spectroscopy in the deep ultraviolet frequency range via frequency conversion – a spectral domain yet poorly covered in today’s spectrometers. Compared to complex, actively stabilized laser systems, the compact size facilitates real-world applications, such as atmospheric sensing and high-precision distance measurements.
Wissenschaftliche Ansprechpartner:
Prof. Dr. Oleg Pronin, Laser Technology & Spectroscopy, e-mail oleg.pronin@hsu-hh.de
Originalpublikation:
Fritsch, K., Hofer, T., Brons, J. et al. Dual-comb thin-disk oscillator. Nat Commun 13, 2584 (2022).
DOI: https://doi.org/10.1038/s41467-022-30078-0
Media Contact
All latest news from the category: Process Engineering
This special field revolves around processes for modifying material properties (milling, cooling), composition (filtration, distillation) and type (oxidation, hydration).
Valuable information is available on a broad range of technologies including material separation, laser processes, measuring techniques and robot engineering in addition to testing methods and coating and materials analysis processes.
Newest articles
Sea slugs inspire highly stretchable biomedical sensor
USC Viterbi School of Engineering researcher Hangbo Zhao presents findings on highly stretchable and customizable microneedles for application in fields including neuroscience, tissue engineering, and wearable bioelectronics. The revolution in…
Twisting and binding matter waves with photons in a cavity
Precisely measuring the energy states of individual atoms has been a historical challenge for physicists due to atomic recoil. When an atom interacts with a photon, the atom “recoils” in…
Nanotubes, nanoparticles, and antibodies detect tiny amounts of fentanyl
New sensor is six orders of magnitude more sensitive than the next best thing. A research team at Pitt led by Alexander Star, a chemistry professor in the Kenneth P. Dietrich…
