Coherent all-optical tuning of a large-area phase-gradient metasurface
Coherent all-optical tuning of a large-area phase-gradient metasurface
Tunable active metasurfaces have become a major research focus in recent years. Among tuning mechanisms, all-optical coherent control stands out because it requires no material or geometric change, enabling low-energy, interference-based modulation of amplitude, phase, and polarization in ultrathin devices. However, when applied to phase-gradient metasurfaces, coherent control has been limited to small apertures effectively confined to a single Fresnel zone, leading to large divergence and degraded beam quality. Here, we propose and numerically validate a scalable method that enables large-area coherent control. The key idea is to use coherent illumination to tune the phase gradient within each Fresnel zone, while a direct search algorithm optimizes zone-by-zone parameters to meet system-level targets. Using this principle, we demonstrate continuous tuning of a large-area metasurface for continuous beam steering without per-meta-atom phase actuation. The same framework applies broadly to continuously tunable phase-gradient optics, including varifocal metalenses, parfocal zoom metalenses, tunable axicons, and related dynamic focusing elements.
344-350
He, Zhiping
69a86454-2515-4cda-b660-b3804d1725d8
Fang, Xu
96b4b212-496b-4d68-82a4-06df70f94a86
Hu, Juejun
91159f43-026a-47f5-9033-2bd4608cac06
29 January 2026
He, Zhiping
69a86454-2515-4cda-b660-b3804d1725d8
Fang, Xu
96b4b212-496b-4d68-82a4-06df70f94a86
Hu, Juejun
91159f43-026a-47f5-9033-2bd4608cac06
He, Zhiping, Fang, Xu and Hu, Juejun
(2026)
Coherent all-optical tuning of a large-area phase-gradient metasurface.
Journal of the Optical Society of America B, 43 (2), .
(doi:10.1364/JOSAB.582723).
Abstract
Tunable active metasurfaces have become a major research focus in recent years. Among tuning mechanisms, all-optical coherent control stands out because it requires no material or geometric change, enabling low-energy, interference-based modulation of amplitude, phase, and polarization in ultrathin devices. However, when applied to phase-gradient metasurfaces, coherent control has been limited to small apertures effectively confined to a single Fresnel zone, leading to large divergence and degraded beam quality. Here, we propose and numerically validate a scalable method that enables large-area coherent control. The key idea is to use coherent illumination to tune the phase gradient within each Fresnel zone, while a direct search algorithm optimizes zone-by-zone parameters to meet system-level targets. Using this principle, we demonstrate continuous tuning of a large-area metasurface for continuous beam steering without per-meta-atom phase actuation. The same framework applies broadly to continuously tunable phase-gradient optics, including varifocal metalenses, parfocal zoom metalenses, tunable axicons, and related dynamic focusing elements.
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Coherent manuscript_XF
- Accepted Manuscript
Text
josab-43-2-344
- Version of Record
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Accepted/In Press date: 10 January 2026
e-pub ahead of print date: 13 January 2026
Published date: 29 January 2026
Identifiers
Local EPrints ID: 511251
URI: http://eprints.soton.ac.uk/id/eprint/511251
ISSN: 0740-3224
PURE UUID: 152ab5bd-e977-4428-bff9-ecad5ec2ea9f
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Date deposited: 11 May 2026 16:31
Last modified: 12 May 2026 01:47
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Contributors
Author:
Zhiping He
Author:
Xu Fang
Author:
Juejun Hu
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