Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit

Sean P. Bommer; Christopher Panuski; Benoit Guilhabert; Zhongyi Xia; Jack A. Smith; Martin D. Dawson; Dirk Englund; Michael J. Strain

doi:10.1038/s41467-025-60957-1

Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit

Sean P. Bommer^*, Christopher Panuski, Benoit Guilhabert, Zhongyi Xia, Jack A. Smith, Martin D. Dawson, Dirk Englund, Michael J. Strain^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

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Abstract

Photonic crystal cavities (PhCCs) can confine optical fields in ultra-small volumes, enabling efficient light-matter interactions for quantum and non-linear optics, sensing and all-optical signal processing. The inherent nanometric tolerances of micro-fabrication platforms can induce cavity resonant wavelength shifts two-orders of magnitude larger than cavity linewidths, prohibiting fabrication of arrays of nominally identical devices. We address this device variability by fabricating PhCCs as releasable pixels that can be transferred from their native substrate to a receiver where ordered micro-assembly can overcome the inherent fabrication variance. We demonstrate the measurement, binning and transfer of 119 PhCCs in a single session, producing spatially ordered arrays of PhCCs, sorted by resonant wavelength. Furthermore, the rapid in-situ measurement of the devices enables measurements of the PhCCs dynamic response to the print process for the first time, showing plastic and elastic effects in the seconds to hours range.

Original language	English
Article number	5994
Number of pages	9
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-60957-1
Publication status	Published - 1 Jul 2025

Funding

The authors acknowledge funding from the following sources: Royal Academy of Engineering (Research Chairs and Senior Research Fellowships); Engineering and Physical Sciences Research Council (EP/R03480X/1, EP/V004859/1); Innovate UK (50414).

Keywords

photonic crystal cavities
optics

Access to Document

10.1038/s41467-025-60957-1Licence: CC BY 4.0

Bommer-etal-NC-2025-Transfer-printing-micro-assembly-of-silicon-photonic-crystal-cavity-arraysFinal published version, 1.94 MBLicence: CC BY 4.0

Cite this

@article{965abacbccc844eb9ef58ce32edfa895,

title = "Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit",

abstract = "Photonic crystal cavities (PhCCs) can confine optical fields in ultra-small volumes, enabling efficient light-matter interactions for quantum and non-linear optics, sensing and all-optical signal processing. The inherent nanometric tolerances of micro-fabrication platforms can induce cavity resonant wavelength shifts two-orders of magnitude larger than cavity linewidths, prohibiting fabrication of arrays of nominally identical devices. We address this device variability by fabricating PhCCs as releasable pixels that can be transferred from their native substrate to a receiver where ordered micro-assembly can overcome the inherent fabrication variance. We demonstrate the measurement, binning and transfer of 119 PhCCs in a single session, producing spatially ordered arrays of PhCCs, sorted by resonant wavelength. Furthermore, the rapid in-situ measurement of the devices enables measurements of the PhCCs dynamic response to the print process for the first time, showing plastic and elastic effects in the seconds to hours range.",

keywords = "photonic crystal cavities, optics",

author = "Bommer, \{Sean P.\} and Christopher Panuski and Benoit Guilhabert and Zhongyi Xia and Smith, \{Jack A.\} and Dawson, \{Martin D.\} and Dirk Englund and Strain, \{Michael J.\}",

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language = "English",

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T1 - Transfer printing micro-assembly of silicon photonic crystal cavity arrays

T2 - beating the fabrication tolerance limit

AU - Bommer, Sean P.

AU - Panuski, Christopher

AU - Guilhabert, Benoit

AU - Xia, Zhongyi

AU - Smith, Jack A.

AU - Dawson, Martin D.

AU - Englund, Dirk

AU - Strain, Michael J.

PY - 2025/7/1

Y1 - 2025/7/1

N2 - Photonic crystal cavities (PhCCs) can confine optical fields in ultra-small volumes, enabling efficient light-matter interactions for quantum and non-linear optics, sensing and all-optical signal processing. The inherent nanometric tolerances of micro-fabrication platforms can induce cavity resonant wavelength shifts two-orders of magnitude larger than cavity linewidths, prohibiting fabrication of arrays of nominally identical devices. We address this device variability by fabricating PhCCs as releasable pixels that can be transferred from their native substrate to a receiver where ordered micro-assembly can overcome the inherent fabrication variance. We demonstrate the measurement, binning and transfer of 119 PhCCs in a single session, producing spatially ordered arrays of PhCCs, sorted by resonant wavelength. Furthermore, the rapid in-situ measurement of the devices enables measurements of the PhCCs dynamic response to the print process for the first time, showing plastic and elastic effects in the seconds to hours range.

AB - Photonic crystal cavities (PhCCs) can confine optical fields in ultra-small volumes, enabling efficient light-matter interactions for quantum and non-linear optics, sensing and all-optical signal processing. The inherent nanometric tolerances of micro-fabrication platforms can induce cavity resonant wavelength shifts two-orders of magnitude larger than cavity linewidths, prohibiting fabrication of arrays of nominally identical devices. We address this device variability by fabricating PhCCs as releasable pixels that can be transferred from their native substrate to a receiver where ordered micro-assembly can overcome the inherent fabrication variance. We demonstrate the measurement, binning and transfer of 119 PhCCs in a single session, producing spatially ordered arrays of PhCCs, sorted by resonant wavelength. Furthermore, the rapid in-situ measurement of the devices enables measurements of the PhCCs dynamic response to the print process for the first time, showing plastic and elastic effects in the seconds to hours range.

KW - photonic crystal cavities

KW - optics

UR - https://arxiv.org/abs/2406.20010

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Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit

Abstract

Funding

Keywords

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Other files and links

Fingerprint

Zero-change manufacturing of photonic interconnects for silicon electronics (IntraChip)

'Hetero-print': A holistic approach to transfer-printing for heterogeneous integration in manufacturing

Data for "Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit"

Cite this

Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Projects

Zero-change manufacturing of photonic interconnects for silicon electronics (IntraChip)

'Hetero-print': A holistic approach to transfer-printing for heterogeneous integration in manufacturing

Datasets

Data for "Transfer printing micro-assembly of silicon photonic crystal cavity arrays: beating the fabrication tolerance limit"

Cite this