Ultracompact programmable silicon photonics using layers of low-loss phase-change material Sb2Se3 of increasing thickness
Ultracompact programmable silicon photonics using layers of low-loss phase-change material Sb2Se3 of increasing thickness
High-performance programmable silicon photonic circuits are considered to be a critical part of next-generation architectures for optical processing, photonic quantum circuits, and neural networks. Low-loss optical phase-change materials (PCMs) offer a promising route toward nonvolatile free-form control of light. Here, we exploit the direct-write digital patterning of waveguides using layers of the PCM Sb 2Se 3 with thickness values from 20 to 100 nm, demonstrating the scaling of induced optical phase shift with thickness and the ability to strongly increase the effect per pixel for thicker layers. We exploit the excellent refractive index matching between Sb 2Se 3 and silicon to achieve a low-loss hybrid platform for programmable photonics. A 5-fold reduction in the modulation length of a Mach-Zehnder interferometer is achieved with increasing thickness compared to the 20 nm thin-film Sb 2Se 3 devices, which decreased to 5 μm in this work. Application of the thicker PCM layers in direct-write digital programming of a multimode interferometer shows a corresponding 3-fold reduction of the number of programmed pixels to below 10 pixels per device. The demonstrated scaling of performance with Sb 2Se 3 layer thickness is important for establishing the optimum working range for hybrid silicon-Sb 2Se 3 devices and holds promise for achieving ultracompact, programmable photonic circuits.
SbSe, phase change, programmable photonic devices, silicon photonics, Sb Se
1382-1391
Blundell, Sophie
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Radford, Thomas W.
71ac0576-afc9-43c4-b0bf-c51719afe551
Ajia, Idris A.
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Lawson, Daniel
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Yan, Xingzhao
320b9089-1fb3-485a-8c1f-45fb1f86efa0
Banakar, Mehdi
ad56fc0a-728c-4abb-8be5-74318bb2758e
Thomson, David J.
17c1626c-2422-42c6-98e0-586ae220bcda
Zeimpekis, Ioannis
df8606c0-5d27-46da-9e98-8296d6d7249a
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
19 March 2025
Blundell, Sophie
bfd3df70-0624-49e3-b694-f82922ec03b6
Radford, Thomas W.
71ac0576-afc9-43c4-b0bf-c51719afe551
Ajia, Idris A.
6c3d6040-2701-43c9-a7d1-a55ba45ab510
Lawson, Daniel
e26cb19c-c680-46b9-a551-f0b584694a12
Yan, Xingzhao
320b9089-1fb3-485a-8c1f-45fb1f86efa0
Banakar, Mehdi
ad56fc0a-728c-4abb-8be5-74318bb2758e
Thomson, David J.
17c1626c-2422-42c6-98e0-586ae220bcda
Zeimpekis, Ioannis
df8606c0-5d27-46da-9e98-8296d6d7249a
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Blundell, Sophie, Radford, Thomas W., Ajia, Idris A., Lawson, Daniel, Yan, Xingzhao, Banakar, Mehdi, Thomson, David J., Zeimpekis, Ioannis and Muskens, Otto L.
(2025)
Ultracompact programmable silicon photonics using layers of low-loss phase-change material Sb2Se3 of increasing thickness.
ACS Photonics, 12 (3), .
(doi:10.1021/acsphotonics.4c01789).
Abstract
High-performance programmable silicon photonic circuits are considered to be a critical part of next-generation architectures for optical processing, photonic quantum circuits, and neural networks. Low-loss optical phase-change materials (PCMs) offer a promising route toward nonvolatile free-form control of light. Here, we exploit the direct-write digital patterning of waveguides using layers of the PCM Sb 2Se 3 with thickness values from 20 to 100 nm, demonstrating the scaling of induced optical phase shift with thickness and the ability to strongly increase the effect per pixel for thicker layers. We exploit the excellent refractive index matching between Sb 2Se 3 and silicon to achieve a low-loss hybrid platform for programmable photonics. A 5-fold reduction in the modulation length of a Mach-Zehnder interferometer is achieved with increasing thickness compared to the 20 nm thin-film Sb 2Se 3 devices, which decreased to 5 μm in this work. Application of the thicker PCM layers in direct-write digital programming of a multimode interferometer shows a corresponding 3-fold reduction of the number of programmed pixels to below 10 pixels per device. The demonstrated scaling of performance with Sb 2Se 3 layer thickness is important for establishing the optimum working range for hybrid silicon-Sb 2Se 3 devices and holds promise for achieving ultracompact, programmable photonic circuits.
Text
blundell-et-al-2025-ultracompact-programmable-silicon-photonics-using-layers-of-low-loss-phase-change-material-sb2se3
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More information
Accepted/In Press date: 27 February 2025
e-pub ahead of print date: 7 March 2025
Published date: 19 March 2025
Keywords:
SbSe, phase change, programmable photonic devices, silicon photonics, Sb Se
Identifiers
Local EPrints ID: 501269
URI: http://eprints.soton.ac.uk/id/eprint/501269
ISSN: 2330-4022
PURE UUID: 6caf741a-a3f1-4374-90d1-6273f9cb6eee
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Date deposited: 28 May 2025 16:36
Last modified: 22 Aug 2025 02:26
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Contributors
Author:
Sophie Blundell
Author:
Thomas W. Radford
Author:
Daniel Lawson
Author:
Xingzhao Yan
Author:
Mehdi Banakar
Author:
David J. Thomson
Author:
Ioannis Zeimpekis
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