Scaling silicon photonic switch fabrics for data center interconnection networks

Nikolova, Dessislava; Rumley, Sébastien; Calhoun, David M.; Li, Qi; Hendry, Robert; Samadi, Payman; Bergman, Keren

doi:10.1364/oe.23.001159

Cited by 119 publications

(39 citation statements)

References 50 publications

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“…Ultracompact chip-integrated all-optical logic half-and full-adders are essential and core components in the field of optical computing system. The practical on-chip integration applications require several key indexes for these nanoscale all-optical logic devices: ultrasmall feature size, ultralow threshold power, ultrahigh contrast ratio, as well as on-chip trigger [2,3]. More often than not, highly nonlinear fibers [4][5][6], optical asymmetric demultiplexers [7,8], and bulk periodically poled lithium niobate crystals [9][10][11] are used to demonstrate all-optical logic functions.…”

Section: Introductionmentioning

confidence: 99%

Ultracompact all-optical full-adder and half-adder based on nonlinear plasmonic nanocavities

Xie

Niu

et al. 2017

Nanophotonics

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Ultracompact chip-integrated all-optical halfand full-adders are realized based on signal-light induced plasmonic-nanocavity-modes shift in a planar plasmonic microstructure covered with a nonlinear nanocomposite layer, which can be directly integrated into plasmonic circuits. Tremendous nonlinear enhancement is obtained for the nanocomposite cover layer, attributed to resonant excitation, slow light effect, as well as field enhancement effect provided by the plasmonic nanocavity. The feature size of the device is <15 μm, which is reduced by three orders of magnitude compared with previous reports. The operating threshold power is determined to be 300 μW (corresponding to a threshold intensity of 7.8 MW/cm 2 ), which is reduced by two orders of magnitude compared with previous reports. The intensity contrast ratio between two output logic states, "1" and "0," is larger than 27 dB, which is among the highest values reported to date. Our work is the first to experimentally realize on-chip halfand full-adders based on nonlinear plasmonic nanocavities having an ultrasmall feature size, ultralow threshold power, and high intensity contrast ratio simultaneously.This work not only provides a platform for the study of nonlinear optics, but also paves a way to realize ultrahighspeed signal computing chips.

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Section: Introductionmentioning

confidence: 99%

Ultracompact all-optical full-adder and half-adder based on nonlinear plasmonic nanocavities

Xie

Niu

et al. 2017

Nanophotonics

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“…The transition to photonic devices would provide increased functionality, reliability, low cost and compact size, all of which are attractive for optical communications and bio-sensing, among other areas. Furthermore, they support higher bandwidth, denser interconnects, with higher efficiency in addition to reduced cross talk, latency, and specifically power consumption [3,4]. In particular, the silicon photonics platform is becoming the preferred technology for photonic integrated circuits [5,6], due to its high index contrast, low optical loss in the major telecommunications optical windows, and established CMOS fabrication technology.…”

Section: Introductionmentioning

confidence: 99%

Athermal silicon optical add-drop multiplexers based on thermo-optic coefficient tuning of sol-gel material

Namnabat¹,

Kim²,

Jones³

et al. 2017

Opt. Express

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Silicon photonics has gained interest for its potential to provide higher efficiency, bandwidth and reduced power consumption compared to electrical interconnects in datacenters and high performance computing environments. However, it is well known that silicon photonic devices suffer from temperature fluctuations due to silicon's high thermo-optic coefficient and therefore, temperature control in many applications is required. Here we present an athermal optical add-drop multiplexer fabricated from ring resonators. We used a sol-gel inorganic-organic hybrid material as an alternative to previously used materials such as polymers and titanium dioxide. In this work we studied the thermal curing parameters of the sol-gel and their effect on thermal wavelength shift of the rings. With this method, we were able to demonstrate a thermal shift down to -6.8 pm/℃ for transverse electric (TE) polarization in ring resonators with waveguide widths of 325 nm when the sol-gel was cured at 130℃ for 10.5 hours. We also achieved thermal shifts below 1 pm/℃ for transverse magnetic (TM) polarization in the C band under different curing conditions. Curing time compared to curing temperature shows to be the most important factor to control sol-gel's thermo-optic value in order to obtain an athermal device in a wide temperature range.

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“…Until now, silicon switches have been mostly based on two different photonic structures: ring resonators and Mach-Zehnder interferometric (MZI) structures. Ring resonators allow minimizing the footprint but at expenses of a narrow optical bandwidth which can only be increased by using more complex ring structures or switching techniques [2][3][4]. Furthermore, an additional tuning mechanism, which will increase the total power consumption, is also necessary to counteract possible fabrication deviations [5].…”

Section: Introductionmentioning

confidence: 99%

High performace silicon 2x2 optical switch based on a thermo-optically tunable multimode interference coupler and efficient electrodes

Rosa¹,

Gutiérrez²,

Brimont³

et al. 2016

Opt. Express

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2 is proposed and demonstrated. The MMI structure has been optimized using a silica trench acting as a thermal isolator without introducing any substantial loss penalty or crosstalk degradation. Furthermore, the electrodes performance have significantly been improved via engineering the heater geometry and using two metallization steps. Thereby, a drastic power consumption reduction of around 90% has been demonstrated yielding to values as low as 24.9 mW. Furthermore, very fast switching times of only 1.19 µs have also been achieved.

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Scaling silicon photonic switch fabrics for data center interconnection networks

Cited by 119 publications

References 50 publications

Ultracompact all-optical full-adder and half-adder based on nonlinear plasmonic nanocavities

Ultracompact all-optical full-adder and half-adder based on nonlinear plasmonic nanocavities

Athermal silicon optical add-drop multiplexers based on thermo-optic coefficient tuning of sol-gel material

High performace silicon 2x2 optical switch based on a thermo-optically tunable multimode interference coupler and efficient electrodes

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