Have it all with the Koheras HARMONIK
We suggest you go for our high-powered, frequency-doubled Koheras HARMONIK fiber laser system. This system gives you a unique combination of high power, low noise, excellent beam quality, and a narrow linewidth.
Do you need more details? With the HARMONIK, you can get an output power of > 8 W at 780 nm, a beam quality of M2 < 1.1, and a linewidth of < 30 kHz or < 0.4 kHz depending on the model. It’s mode-hop-free, and here you can get an overview of the noise data:
|Max. phase noise||-66dB((rad/√Hz)/m)@10Hz
|RIN peak||Appr. 1.0 MHz||Appr. 0.7 MHz|
|RIN level||< -117 dBc/Hz @ peak
< -137 dBc/Hz @ 10 MHz
|< -97 dBc/Hz @ peak
< -132 dBc/Hz @ 10 MHz
|Optical S/N (50 pm res.)||> 50 dB||> 50 dB|
Go to the HARMONIK product page for more information.
This laser is robust enough for oil rigs yet sophisticated enough for the lab
Our fiber laser design is inherently compact and robust. It is developed for a lifetime of above 10 years in demanding environments where uptime is critical. With failure rates lower than 1%, we proudly deliver the most reliable low-noise lasers on the market. Alignment-free and maintenance-free.
The industrial-grade lasers have a rugged design, a stable performance unaffected by changing environmental conditions, and wide temperature ranges in the field as well as the lab. We deliver lasers to the most advanced laboratories worldwide such as The Quantum Hub at the University of Birmingham.
We have more than 15,000 Koheras lasers deployed in the harshest environments on – and off – the planet. We have lasers on oil rigs, submarines, wind turbines, and even in space. With over 20 years of experience, we know they last. Also in your lab.
What have others done with our Koheras lasers?
- Ultranarrow bandwidth Faraday atomic filter approaching natural linewidth based on cold atoms by Wei Zhuang, Yang Zhao, Shaokai Wang, Zhanjun Fang, Fang Fang, Tianchu Li, published in Chinese Optics Letters, 2021.
- Performance of an optical single-sideband laser system for atom interferometry by Clemens Rammeloo, Lingxiao Zhu, Yu-Hung Lien, Kai Bongs, Michael Holynski, published in Journal of the Optical Society of America B, 2020.
- Optical frequency generation using fiber Bragg grating filters for applications in portable quantum sensing by C. D. Macrae, K. Bongs, M. Holynski, published in Atomic Physics, 2020.
- Doppler Compensated Cavity For Atom Interferometry by Rustin Nourshargh, Sam Hedges, Mehdi Langlois, Kai Bongs, Michael Holynski, published in Atomic Physics, 2020.
- Time-scale Generation Methods Based on an Optical Clock by Artem Gribov, Denis Sutyrin, Oleg Berdasov, Sergey Antropov, Gleb Belotelov, Evgeniya Stelmashenko, Aleksei Kostin, Mikhail Gurov, Alexander Malimon, Daria Fedorova, Roman Balaev, Sergey Slyusarev published in IEEE Xplore, 2020.
- Multi-second magnetic coherence in a single domain spinor Bose–Einstein condensate by Silvana Palacios, Simon Coop, Pau Gomez, Thomas Vanderbruggen, Y. Natali Martinez de Escobar, Martijn Jasperse, Morgan W Mitchell, published in New Journal of Physics, 2018.
- Optical frequency standard of continuous wave for fiber communication based on optical comb by Ruiyuan Liu, Ye Li, Cheng Qian, Dawei Li, Jianxiao Leng, Jianye Zhao, published in Optics Communications, 2018.