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Towards fibre-like loss for photonic integration from violet to near-infrared

Towards fibre-like loss for photonic integration from violet to near-infrared
Towards fibre-like loss for photonic integration from violet to near-infrared
Over the past decades, remarkable progress has been made in reducing the loss of photonic integrated circuits (PICs) within the telecom band, facilitating on-chip applications spanning low-noise optical and microwave synthesis, to lidar and photonic artificial intelligence engines. However, several obstacles arise from the marked increase in material absorption and scattering losses at shorter wavelengths, which prominently elevate power requirements and limit performance in the visible and near-visible spectrum. Here we present an ultralow-loss PIC platform based on germano-silicate—the material underlying the extraordinary performance of optical fibre—but realized by a fully CMOS-foundry-compatible process. These PICs achieve resonator Q factors surpassing 180 million from violet to telecom wavelengths. They also attain a 10-dB higher quality factor without thermal treatment in the telecom band, expanding opportunities for heterogeneous integration with active components. Other features of this platform include readily engineered waveguide dispersion, acoustic mode confinement and large-mode-area-induced thermal stability—each demonstrated by soliton microcomb generation, stimulated Brillouin lasing and low-frequency-noise self-injection locking, respectively. The success of these germano-silicate PICs can ultimately enable fibre-like loss onto a chip, leading to an additional 20-dB improvement in waveguide loss over the current highest performance photonic platforms. Moreover, the performance abilities demonstrated here bridge ultralow-loss PIC technology to optical clocks, precision navigation systems and quantum sensors.
1476-4687
338-344
Chen, Hao Jing
38e7c93d-3cb8-4ccc-88a7-7c058b6fe47a
Colburn, Kellan
3042ec2b-3cde-4fb5-b869-dc6c75d5e442
Liu, Peng
3ae0ffd7-081c-40b5-8bf0-73c0a16b98bd
Yan, Hongrui
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Hou, Hanfei
39b370ed-7138-4541-b83c-788570ee7138
Ge, Jinhao
af5e9f0d-512e-4059-96ab-e476ca0bd50c
Liu, Jin-Yu
e64a4e88-208e-43f6-945e-69e28c77374d
Yuan, Zhiquan
57926ea8-6a8e-4503-9217-93eb7119a5a9
Lehan, Phineas
486accf8-4006-43b3-9f42-94053dbe60aa
Bouwmeester, Dirk
f83984fd-a0b3-4696-a759-d5f3de669ec8
Holmes, Christopher
16306bb8-8a46-4fd7-bb19-a146758e5263
Gates, James
b71e31a1-8caa-477e-8556-b64f6cae0dc2
Blauvelt, Henry
142a9141-e8ec-45b7-a48f-902018620874
Vahala, Kerry
42cf33c0-8c48-4025-b28e-23a4dcdf8412
Chen, Hao Jing
38e7c93d-3cb8-4ccc-88a7-7c058b6fe47a
Colburn, Kellan
3042ec2b-3cde-4fb5-b869-dc6c75d5e442
Liu, Peng
3ae0ffd7-081c-40b5-8bf0-73c0a16b98bd
Yan, Hongrui
c0cdccff-5ae2-4491-8082-2e72daa75b4e
Hou, Hanfei
39b370ed-7138-4541-b83c-788570ee7138
Ge, Jinhao
af5e9f0d-512e-4059-96ab-e476ca0bd50c
Liu, Jin-Yu
e64a4e88-208e-43f6-945e-69e28c77374d
Yuan, Zhiquan
57926ea8-6a8e-4503-9217-93eb7119a5a9
Lehan, Phineas
486accf8-4006-43b3-9f42-94053dbe60aa
Bouwmeester, Dirk
f83984fd-a0b3-4696-a759-d5f3de669ec8
Holmes, Christopher
16306bb8-8a46-4fd7-bb19-a146758e5263
Gates, James
b71e31a1-8caa-477e-8556-b64f6cae0dc2
Blauvelt, Henry
142a9141-e8ec-45b7-a48f-902018620874
Vahala, Kerry
42cf33c0-8c48-4025-b28e-23a4dcdf8412

Chen, Hao Jing, Colburn, Kellan, Liu, Peng, Yan, Hongrui, Hou, Hanfei, Ge, Jinhao, Liu, Jin-Yu, Yuan, Zhiquan, Lehan, Phineas, Bouwmeester, Dirk, Holmes, Christopher, Gates, James, Blauvelt, Henry and Vahala, Kerry (2026) Towards fibre-like loss for photonic integration from violet to near-infrared. Nature, 649 (8096), 338-344. (doi:10.1038/s41586-025-09889-w).

Record type: Article

Abstract

Over the past decades, remarkable progress has been made in reducing the loss of photonic integrated circuits (PICs) within the telecom band, facilitating on-chip applications spanning low-noise optical and microwave synthesis, to lidar and photonic artificial intelligence engines. However, several obstacles arise from the marked increase in material absorption and scattering losses at shorter wavelengths, which prominently elevate power requirements and limit performance in the visible and near-visible spectrum. Here we present an ultralow-loss PIC platform based on germano-silicate—the material underlying the extraordinary performance of optical fibre—but realized by a fully CMOS-foundry-compatible process. These PICs achieve resonator Q factors surpassing 180 million from violet to telecom wavelengths. They also attain a 10-dB higher quality factor without thermal treatment in the telecom band, expanding opportunities for heterogeneous integration with active components. Other features of this platform include readily engineered waveguide dispersion, acoustic mode confinement and large-mode-area-induced thermal stability—each demonstrated by soliton microcomb generation, stimulated Brillouin lasing and low-frequency-noise self-injection locking, respectively. The success of these germano-silicate PICs can ultimately enable fibre-like loss onto a chip, leading to an additional 20-dB improvement in waveguide loss over the current highest performance photonic platforms. Moreover, the performance abilities demonstrated here bridge ultralow-loss PIC technology to optical clocks, precision navigation systems and quantum sensors.

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s41586-025-09889-w - Version of Record
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Accepted/In Press date: 10 November 2025
e-pub ahead of print date: 7 January 2026
Published date: 8 January 2026
Related URLs:
Learn more about Zepler Institute for Photonics and Nanoelectronics research

Identifiers

Local EPrints ID: 507984
URI: http://eprints.soton.ac.uk/id/eprint/507984
DOI: doi:10.1038/s41586-025-09889-w
ISSN: 1476-4687
PURE UUID: 13ee9bde-e8d6-463c-9913-9c9b16222eca
ORCID for Christopher Holmes: ORCID iD orcid.org/0000-0001-9021-3760
ORCID for James Gates: ORCID iD orcid.org/0000-0001-8671-5987

Catalogue record

Date deposited: 09 Jan 2026 17:32
Last modified: 10 Jan 2026 03:05

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Contributors

Author: Hao Jing Chen
Author: Kellan Colburn
Author: Peng Liu
Author: Hongrui Yan
Author: Hanfei Hou
Author: Jinhao Ge
Author: Jin-Yu Liu
Author: Zhiquan Yuan
Author: Phineas Lehan
Author: Dirk Bouwmeester
Author: Christopher Holmes ORCID iD
Author: James Gates ORCID iD
Author: Henry Blauvelt
Author: Kerry Vahala

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