Resonator embedded photonic crystal surface emitting lasers

Abstract

The finite size of 2D photonic crystals results in them being a lossy resonator, with the normally emitting modes of conventional photonic crystal surface emitting lasers (PCSELs) differing in photon lifetime via their different radiative rates, and the different in-plane losses of higher order spatial modes. As a consequence, the fundamental spatial mode (lowest in-plane loss) with lowest out-of-plane scattering is the primary lasing mode. For electrically driven PCSELs, as current is increased, incomplete gain clamping results in additional spatial (and spectral) modes leading to a reduction in beam quality. A number of approaches have been discussed to enhance the area (power) scalability of epitaxy regrown PCSELs through careful design of the photonic crystal atom1–3. None of these approaches tackle the inflexibility in being unable to independently modify the photon lifetime of the different modes at the Γ2 point. As a method to introduce design flexibility, resonator embedded photonic crystal surface emitting lasers (REPCSELs) are introduced. This device, combining comparatively low coupling strength photonic crystal structures along with perimeter mirrors, allow a Fabry–Pérot resonance effect to be realised that provides wavelength selective modification of the photon lifetime. We show that surface emission of different surface emitting modes may be selectively enhanced, effectively changing the character of the modes at the Γ2 point. This is a consequence of the selective modification of in-plane loss for particular modes, and is dependent upon the alignment of the photonic crystal (PhC) band-structure and distributed Bragg reflectors’ (DBRs) reflectance spectrum. These findings offer new avenues in surface emitting laser diode engineering. The use of DBRs to reduce the lateral size of a PCSEL opens the route to small, low threshold current (Ith), high output efficiency epitaxy regrown PCSELs for high-speed communication and power sensitive sensing applications.

Publication DOI: https://doi.org/10.1038/s44310-024-00014-9
Divisions: College of Engineering & Physical Sciences > Aston Institute of Photonics Technology (AIPT)
College of Engineering & Physical Sciences
Funding Information: This work was supported by Innovate UK Projects; “LOCAL” (Grant no. 80398), “ZEUS” (Grant no. 10049787) and “TITAN” (Grant no. 10001778)
Additional Information: © The Author(s) 2024. This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.
Publication ISSN: 2948-216X
Last Modified: 29 Oct 2024 16:08
Date Deposited: 06 Jun 2024 12:51
Full Text Link:
Related URLs: https://www.nat ... 310-024-00014-9 (Publisher URL)
PURE Output Type: Article
Published Date: 2024-06-03
Published Online Date: 2024-06-03
Accepted Date: 2024-03-28
Submitted Date: 2024-01-17
Authors: Bian, Zijun
Zhao, Xingyu
Liu, Jingzhao
Kim, Daehyun
McKenzie, Adam F.
Thoms, Stephen
Reynolds, Paul
Gerrard, Neil D.
Kyaw, Aye S. M.
Grant, James
Rae, Katherine
Orchard, Jonathan R.
Hill, Calum H.
Munro, Connor W.
Ivanov, Pavlo
Childs, David T. D.
Taylor, Richard J. E.
Hogg, Richard A. (ORCID Profile 0000-0002-0781-6809)

Download

[img]

Version: Published Version

License: Creative Commons Attribution

| Preview

Export / Share Citation


Statistics

Additional statistics for this record