High speed silicon electro-optical modulators enhanced via slow light propagation
High speed silicon electro-optical modulators enhanced via slow light propagation
While current optical communication networks efficiently carry and process huge amounts of digital information over large and medium distances, silicon photonics technology has the capacity to meet the ceaselessly increasing demand for bandwidth via energy efficient, inexpensive and mass producible short range optical interconnects. In this context, handling electrical-to-optical data conversion through compact and high speed electro-optical modulators is of paramount importance. To tackle these challenges, we combine the attractive properties of slow light propagation in a nanostructured periodic waveguide together with a high speed semiconductor pn diode, and demonstrate a highly efficient and mass manufacturable 500 µm-long silicon electro-optical device, exhibiting error free modulation up to 20 Gbit/s. These results, supported by modulation rate capabilities reaching 40 Gbit/s, pave a foreseeable way towards dense, low power and ultra fast integrated networks-on-chip for future chip-scale high performance computing systems.
20876-20885
Brimont, A.
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Thomson, D.
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Sanchis, P.
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Herrera, J.
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Gardes, F.Y.
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Fedeli, J.M.
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Reed, G.T.
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Martí, J.
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10 October 2011
Brimont, A.
b0cb00ac-0328-4225-b813-b27732baebf2
Thomson, D.
17c1626c-2422-42c6-98e0-586ae220bcda
Sanchis, P.
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Herrera, J.
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Gardes, F.Y.
7a49fc6d-dade-4099-b016-c60737cb5bb2
Fedeli, J.M.
29a8abed-e7c4-484b-bc28-39da9f42788f
Reed, G.T.
ca08dd60-c072-4d7d-b254-75714d570139
Martí, J.
6e71e500-a056-4d59-b08f-ba1c7873adae
Brimont, A., Thomson, D., Sanchis, P., Herrera, J., Gardes, F.Y., Fedeli, J.M., Reed, G.T. and Martí, J.
(2011)
High speed silicon electro-optical modulators enhanced via slow light propagation.
Optics Express, 19 (21), .
(doi:10.1364/OE.19.020876).
Abstract
While current optical communication networks efficiently carry and process huge amounts of digital information over large and medium distances, silicon photonics technology has the capacity to meet the ceaselessly increasing demand for bandwidth via energy efficient, inexpensive and mass producible short range optical interconnects. In this context, handling electrical-to-optical data conversion through compact and high speed electro-optical modulators is of paramount importance. To tackle these challenges, we combine the attractive properties of slow light propagation in a nanostructured periodic waveguide together with a high speed semiconductor pn diode, and demonstrate a highly efficient and mass manufacturable 500 µm-long silicon electro-optical device, exhibiting error free modulation up to 20 Gbit/s. These results, supported by modulation rate capabilities reaching 40 Gbit/s, pave a foreseeable way towards dense, low power and ultra fast integrated networks-on-chip for future chip-scale high performance computing systems.
Text
oe-19-21-20876
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Accepted/In Press date: 25 July 2011
e-pub ahead of print date: 5 October 2011
Published date: 10 October 2011
Organisations:
Optoelectronics Research Centre, Nanoelectronics and Nanotechnology
Identifiers
Local EPrints ID: 337774
URI: http://eprints.soton.ac.uk/id/eprint/337774
ISSN: 1094-4087
PURE UUID: 68e5f37d-f674-487f-bb23-4e5714248ff4
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Date deposited: 03 May 2012 14:11
Last modified: 15 Mar 2024 03:40
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Contributors
Author:
A. Brimont
Author:
P. Sanchis
Author:
J. Herrera
Author:
J.M. Fedeli
Author:
J. Martí
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