Subwavelength and broadband on-chip mode splitting with shifted junctions
Subwavelength and broadband on-chip mode splitting with shifted junctions
We design and fabricate a sub-wavelength on-chip mode splitter based on the implementation of a shifted junction between a single-mode waveguide and a multimode waveguide. A proper choice of the device parameters enables to split the input beam into a combination of different guided modes of the multimode waveguide, minimizing radiation and reflection losses that amount to ∼ 0.4 dB in our experiments. Because the splitting mechanism does not rely on phase-matching, we achieve broadband operation that could exceed 200 nm bandwidth (<0.5 dB splitting variation). This approach ensures temporal and phase synchronization among the output modes, with applications spanning from the emergent multimode photonics platform to traditional single-mode photonics operations.
24072-24080
Haines, Jack
467fe47a-9676-4709-95ef-8442a907e067
Naik, Pooja uday
f7d0c26e-559c-4262-896b-75df9eb94ede
Ji, Kunhao
92e720a5-e802-4e36-9e51-4c9846df9b56
Vitali, Valerio
4a0d9710-5d64-4703-9554-86d71c4cb0f5
Franz, Yohan
edb6208c-9f65-42c4-965e-b6bc54945602
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Guasoni, Massimiliano
5aa684b2-643e-4598-93d6-bc633870c99a
17 June 2024
Haines, Jack
467fe47a-9676-4709-95ef-8442a907e067
Naik, Pooja uday
f7d0c26e-559c-4262-896b-75df9eb94ede
Ji, Kunhao
92e720a5-e802-4e36-9e51-4c9846df9b56
Vitali, Valerio
4a0d9710-5d64-4703-9554-86d71c4cb0f5
Franz, Yohan
edb6208c-9f65-42c4-965e-b6bc54945602
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Guasoni, Massimiliano
5aa684b2-643e-4598-93d6-bc633870c99a
Haines, Jack, Naik, Pooja uday, Ji, Kunhao, Vitali, Valerio, Franz, Yohan, Petropoulos, Periklis and Guasoni, Massimiliano
(2024)
Subwavelength and broadband on-chip mode splitting with shifted junctions.
Optics Express, 32 (14), .
(doi:10.1364/OE.525394).
Abstract
We design and fabricate a sub-wavelength on-chip mode splitter based on the implementation of a shifted junction between a single-mode waveguide and a multimode waveguide. A proper choice of the device parameters enables to split the input beam into a combination of different guided modes of the multimode waveguide, minimizing radiation and reflection losses that amount to ∼ 0.4 dB in our experiments. Because the splitting mechanism does not rely on phase-matching, we achieve broadband operation that could exceed 200 nm bandwidth (<0.5 dB splitting variation). This approach ensures temporal and phase synchronization among the output modes, with applications spanning from the emergent multimode photonics platform to traditional single-mode photonics operations.
Text
oe-32-14-24072
- Version of Record
More information
Accepted/In Press date: 29 May 2024
Published date: 17 June 2024
Identifiers
Local EPrints ID: 498984
URI: http://eprints.soton.ac.uk/id/eprint/498984
ISSN: 1094-4087
PURE UUID: 1422c4f0-1a64-416d-958c-de842c5202a9
Catalogue record
Date deposited: 06 Mar 2025 17:33
Last modified: 17 Sep 2025 02:13
Export record
Altmetrics
Contributors
Author:
Jack Haines
Author:
Pooja uday Naik
Author:
Kunhao Ji
Author:
Valerio Vitali
Author:
Yohan Franz
Author:
Periklis Petropoulos
Author:
Massimiliano Guasoni
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics