Engineering of closely packed silicon-on-isolator waveguide arrays for mode division multiplexing applications

Isabella Cerutti; Nicola Andriolli; Philippe Velha

doi:10.1364/JOSAB.34.000497

Journal of the Optical Society of America B
Vol. 34,
Issue 2,
pp. 497-506
(2017)
•https://doi.org/10.1364/JOSAB.34.000497

Engineering of closely packed silicon-on-isolator waveguide arrays for mode division multiplexing applications

Isabella Cerutti, Nicola Andriolli, and Philippe Velha

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Isabella Cerutti, Nicola Andriolli, and Philippe Velha, "Engineering of closely packed silicon-on-isolator waveguide arrays for mode division multiplexing applications," J. Opt. Soc. Am. B 34, 497-506 (2017)

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- Geometrical Optics
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About this Article
History
- Original Manuscript: October 14, 2016
- Revised Manuscript: December 13, 2016
- Manuscript Accepted: January 4, 2017
- Published: January 31, 2017

Abstract

On-chip optical communications require high-performance, energy-efficient, and scalable multiplexing techniques for enabling high parallelism. Mode division multiplexing (MDM) is gaining momentum, but its scalability is limited by the crosstalk and the (de)multiplexing complexity. To overcome such limitations, this paper proposes the exploitation of super-modes in closely spaced arrays of waveguides. A theoretical approach demonstrates the generation of super-modes achieved by perturbing the uniformity of waveguide arrays. Spectral characterization shows a crosstalk of about $- 20 dB$ on the C band, in a nonuniform array of five silicon-on-isolator waveguides.

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Reference	Type	No. Modes	No. Wavelengths; Band	Max. Width (μm)	Length (μm)	Max. Crosstalk (dB)
[3]	MMW	3 (TE)	N.A.; C-band	0.86	260	−13
[27]	MMW	3 (TE)	3; C-band	1.41	$> 600$ ^a	−12
[7]	MMW	8 (4 TE, 4 TM)	N.A.; C-band	2.363	336	$\sim - 20$
[13]	MMW	4 (TM)	16; C-band	2.363	200	$\sim - 20$
[10]	NAW	5 (3 TE, 2 TM)	N.A.; C-band	1.54	60	−15
[26]	NAW	16 (TE)	N.A.; C-band	17	N.A.	−20
[9]	NAW	25 (TE)	3 bands; C-band	20.45	200	−20
This work	NAW1	5 (TE)	N.A.; C-band	4.4	200	$< - 20$
This work	NAW2	5 (TE)	N.A.; C-band	4.4	200	$< - 22$
This work	NAW (sim)	30 (TE)	N.A.; C-band	26.4	200	−20

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Journal of the Optical Society of America B