High Q-factor reconfigurable microresonators induced in side-coupled optical fibres

Radan Slavík

doi:10.1038/s41377-023-01318-9

Go to Nature Website

Your Location：

Home >

Browse articles >

High Q-factor reconfigurable microresonators induced in side-coupled optical fibres

News & Views

- High Q-factor reconfigurable microresonators induced in side-coupled optical fibres
- Light: Science & Applications Vol. 12, Issue 12, Pages: 2543-2544(2023)
- Affiliations：
  
  Optoelectronics Research Centre, University of Southampton, Southampton SO17 1BJ, UK
- Author bio：
  
  Radan Slavík (r.slavik@soton.ac.uk)
- Funds：
- DOI：10.1038/s41377-023-01318-9
  CLC：
- Published：31 December 2023，
  
  Published Online：23 November 2023，
- Accepted：
Scan QR Code
Slavík, R. High Q-factor reconfigurable microresonators induced in side-coupled optical fibres. Light: Science & Applications, 12, 2543-2544 (2023).
DOI：

Slavík, R. High Q-factor reconfigurable microresonators induced in side-coupled optical fibres. Light: Science & Applications, 12, 2543-2544 (2023). DOI： 10.1038/s41377-023-01318-9.

摘要

Abstract

Recently

significant efforts have been devoted to enable light resonating inside various resonators for long time

leading to high Q factors. Achieving tunability of the free spectral range while maintaining high Q has been

however

challenging.

关键词

Keywords

references

Bahl, G. et al. Stimulated optomechanical excitation of surface acoustic waves in a microdevice.Nat. Commun.2, 403 (2011)..

Lambert, N. J. et al. Coherent conversion between microwave and optical photons - an overview of physical implementations.Adv. Quantum Technol.3, 1900077 (2020)..

Zhu, S. et al. All-optical tunable microlaser based on an ultrahigh-Qerbium-doped hybrid microbottle cavity.ACS Photonics5, 3794–3800 (2018)..

Zhu, S. et al. Tunable Brillouin and Raman microlasers using hybrid microbottle resonators.Nanophotonics8, 931–940 (2019)..

Vassiliev, V.&Sumetsky, M. High Q-factor reconfigurable microresonators induced in side-coupled optical fibres.Light Sci. Appl.12, 197 (2023)..

Sumetsky, M. Theory of SNAP devices: basic equations and comparison with the experiment.Opt. Express20, 22537–22554 (2012)..

Boriskina, S.V. Photonic molecules and spectral engineering. inPhotonic Microresonator Research and Applications(eds. Chremmos, I., Schwelb, O.&Uzunoglu, N. ) 393–421 (Springer, 2010).

Sumetsky, M. Delay of light in an optical bottle resonator with nanoscale radius variation: dispersionless, broadband, and low loss.Phys. Rev. Lett.111, 163901 (2013)..

Sumetsky, M. Optical bottle microresonators.Prog. Quantum Electron.64, 1–30 (2019)..

Buck, J. R.&Kimble, H. J. Optimal sizes of dielectric microspheres for cavity QED with strong coupling.Phys. Rev. A67, 033806 (2003)..

Pfeifer, H. et al. Achievements and perspectives of optical fiber Fabry-Perot cavities.Appl. Phys. B128, 29 (2022)..

Views

Downloads

CSCD

Alert me when the article has been cited

Submit

Tools

Publicity Resources

No data

Related Author

No data

Related Institution

No data

⁰