Buried 3D spot-size converters for silicon photonics
Buried 3D spot-size converters for silicon photonics
In this article, an efficient spot-size converter (SSC) for low-loss optical mode transition between large and small waveguides based upon a buried three-dimensional (3D) taper is demonstrated. The SCC can pave the way for scalable, low-loss coupling between on-chip waveguides of different sizes and with external components such as optical fibers and III-V active components, and it can be a key element in solving the challenges surrounding the economic high volume packaging and assembly of photonic integrated circuits. Through the use of a bespoke fabrication process, continual tapering of the waveguide dimensions both in width and height is achieved, offering minimal perturbance of the optical mode throughout the structure. The SSC exploits the space of the buried oxide (BOX) on a standard silicon-on-insulator wafer, leaving a planar top wafer surface, meaning that, crucially, further processing of the wafer is not inhibited in any way. Fabricated proof-of-concept devices demonstrate coupling between standard single-mode 220 nm thick silicon waveguides and large-core waveguides with dimensions about 3 μm wide and 1.5 μm height with BOX thickness of 2 μm. Coupling losses as low as 0.56 dB are achieved, limited mostly by the material loss of the polysilicon used. Substantial improvements can be yielded by simply changing the infill material and through optimization of the fabrication process and design. The demonstrated SSC approach can further be applied to other photonic platforms such as silicon nitride on insulator and so on.
1102-1108
Zhang, W.
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Ebert, M.
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Reynolds, J.D.
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Chen, B.
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Yan, X.
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Du, H.
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Banakar, M.
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Tran, D.T.
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Littlejohns, C.G.
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Reed, G.T.
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Thomson, D.J.
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13 August 2021
Zhang, W.
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Ebert, M.
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Reynolds, J.D.
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Chen, B.
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Yan, X.
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Du, H.
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Banakar, M.
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Tran, D.T.
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Littlejohns, C.G.
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Reed, G.T.
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Thomson, D.J.
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Zhang, W., Ebert, M., Reynolds, J.D., Chen, B., Yan, X., Du, H., Banakar, M., Tran, D.T., Littlejohns, C.G., Reed, G.T. and Thomson, D.J.
(2021)
Buried 3D spot-size converters for silicon photonics.
Optica, 8 (8), .
(doi:10.1364/OPTICA.431064).
Abstract
In this article, an efficient spot-size converter (SSC) for low-loss optical mode transition between large and small waveguides based upon a buried three-dimensional (3D) taper is demonstrated. The SCC can pave the way for scalable, low-loss coupling between on-chip waveguides of different sizes and with external components such as optical fibers and III-V active components, and it can be a key element in solving the challenges surrounding the economic high volume packaging and assembly of photonic integrated circuits. Through the use of a bespoke fabrication process, continual tapering of the waveguide dimensions both in width and height is achieved, offering minimal perturbance of the optical mode throughout the structure. The SSC exploits the space of the buried oxide (BOX) on a standard silicon-on-insulator wafer, leaving a planar top wafer surface, meaning that, crucially, further processing of the wafer is not inhibited in any way. Fabricated proof-of-concept devices demonstrate coupling between standard single-mode 220 nm thick silicon waveguides and large-core waveguides with dimensions about 3 μm wide and 1.5 μm height with BOX thickness of 2 μm. Coupling losses as low as 0.56 dB are achieved, limited mostly by the material loss of the polysilicon used. Substantial improvements can be yielded by simply changing the infill material and through optimization of the fabrication process and design. The demonstrated SSC approach can further be applied to other photonic platforms such as silicon nitride on insulator and so on.
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optica-8-8-1102
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Accepted/In Press date: 9 July 2021
Published date: 13 August 2021
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Funding Information:
Acknowledgment. G. T. Reed is a Royal Society Wolfson Merit Award holder and is grateful to both the Royal Society and the Wolfson Foundation for funding the award. D. J. Thomson acknowledges funding from the Royal Society for his University Research Fellowship (UF150325).
Identifiers
Local EPrints ID: 481416
URI: http://eprints.soton.ac.uk/id/eprint/481416
ISSN: 2334-2536
PURE UUID: 50fc6901-d95d-4a49-a8da-d1268b248b60
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Date deposited: 25 Aug 2023 17:01
Last modified: 17 Mar 2024 13:27
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Author:
M. Ebert
Author:
J.D. Reynolds
Author:
B. Chen
Author:
H. Du
Author:
D.T. Tran
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