Demonstration of a 17 × 25 Gb/s Heterogeneous III-V/Si DWDM Transmitter based on (De-) Interleaved Quantum Dot Optical Frequency Combs

Cheung, Stanley; Yuan, Yuan; Peng, Yiwei; Kurczveil, Géza; Srinivasan, Sudharsanan; Hu, Yingtao; Descos, Antoine; Liang, Di; Beausoleil, Raymond G.

doi:10.1109/jlt.2022.3196914

Cited by 14 publications

(11 citation statements)

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“…Ring assisted asymmetric MZIs (RAMZIs) find use as filters for flat-top response with improved channel XT 28 , 36 , 44 , 45 . They also find use as linearized transfer functions for improved bit resolution in optical neural networks (ONNs) 78 as well as RF photonics 79 .…”

Section: Resultsmentioning

confidence: 99%

“…The ideal ring resonator coupling for a 1-RAMZI occurs at κ r = 0.89. Details of this device under volatile SISCAP phase shift operation can be found in 28 , 36 , 44 , 45 .…”

Section: Resultsmentioning

confidence: 99%

“…Recently, we have leveraged our heterogeneous III-V/Si optical interconnect platform 28 , 29 to integrate memristors based on semiconductor-insulator-semiconductor capacitors (SISCAP). This platform is suitable for complete device integration of quantum dot (QD) comb lasers 30 – 33 , III-V/Si SISCAP ring modulators 34 – 36 , Si-Ge avalanche photodetectors (APDs) 37 – 40 , QD APDs 28 , 41 , in-situ III-V/Si light monitors 42 , 43 , III-V/Si SISCAP optical filters 44 , 45 , and non-volatile phase shifters 17 – 19 , 22 , 46 – 50 , which are necessary for a fully integrated optical computing chip. These memristors are defined by the semiconductor-oxide interface and act as non-volatile phase shifters due to a multitude of effects described previously.…”

Section: Introductionmentioning

confidence: 99%

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Energy efficient photonic memory based on electrically programmable embedded III-V/Si memristors: switches and filters

Cheung,

Tossoun,

Yuan

et al. 2024

Commun Eng

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Over the past few years, extensive work on optical neural networks has been investigated in hopes of achieving orders of magnitude improvement in energy efficiency and compute density via all-optical matrix-vector multiplication. However, these solutions are limited by a lack of high-speed power power-efficient phase tuners, on-chip non-volatile memory, and a proper material platform that can heterogeneously integrate all the necessary components needed onto a single chip. We address these issues by demonstrating embedded multi-layer HfO2/Al2O3 memristors with III-V/Si photonics which facilitate non-volatile optical functionality for a variety of devices such as Mach-Zehnder Interferometers, and (de-)interleaver filters. The Mach-Zehnder optical memristor exhibits non-volatile optical phase shifts > π with ~33 dB signal extinction while consuming 0 electrical power consumption. We demonstrate 6 non-volatile states each capable of 4 Gbps modulation. (De-) interleaver filters were demonstrated to exhibit memristive non-volatile passband transformation with full set/reset states. Time duration tests were performed on all devices and indicated non-volatility up to 24 hours and beyond. We demonstrate non-volatile III-V/Si optical memristors with large electric-field driven phase shifts and reconfigurable filters with true 0 static power consumption. As a result, co-integrated photonic memristors offer a pathway for in-memory optical computing and large-scale non-volatile photonic circuits.

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Section: Resultsmentioning

confidence: 99%

“…The ideal ring resonator coupling for a 1-RAMZI occurs at κ r = 0.89. Details of this device under volatile SISCAP phase shift operation can be found in 28 , 36 , 44 , 45 .…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Energy efficient photonic memory based on electrically programmable embedded III-V/Si memristors: switches and filters

Cheung,

Tossoun,

Yuan

et al. 2024

Commun Eng

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“…We address the aforementioned challenges by demonstrating a heterogeneous III-V/Si photonic platform capable of non-volatile optical functionality via the CTM effect. In addition, this platform is suitable for seamless integration of quantum dot (QD) comb lasers [51][52][53][54] , III-V/Si MOSCAP ring modulators [55][56][57] , Si-Ge avalanche photodetectors (APDs) [58][59][60][61] , QD APDs 62,63 , in-situ III-V/Si light monitors 64,65 , III-V/Si MOSCAP optical filters 66,67 , and non-volatile phase shifters [38][39][40][41]68 , which are all essential towards realizing a fully integrated optical chip. We believe the co-integration of silicon photonics and non-volatile CTM memory provides a possible near term path towards eliminating the von-Neumann bottleneck as well as playing a role in energy efficient, non-volatile large scale integrated photonics such as: neuromorphic/brain inspired optical networks 5,6,15,26,[69][70][71][72][73][74] , optical switching fabrics for tele/data-communications 75,76 , optical phase arrays 77,78 , quantum networks, and future optical computing architectures.…”

Section: Introductionmentioning

confidence: 99%

Ultra-Power-Efficient Electrically Programmable Photonic Memory on a Heterogeneous III-V/Si Optical Computing Platform

Cheung

Liang

Yuan

et al. 2023

Preprint

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We demonstrate, for the first time, non-volatile charge-trap flash memory (CTM) co-located with heterogeneous III-V/Si photonics. The wafer-bonded III-V/Si CTM cell facilitates non-volatile optical functionality for a variety of devices such as Mach-Zehnder Interferometers (MZIs), asymmetric MZI lattice filters, and ring resonator filters. The MZI CTM exhibits full write/erase operation (100 cycles with 500 states) with wavelength shifts of Δλnon-volatile = 1.16 nm (Δneff,non-volatile ~ 2.5 × 10-4) and a dynamic power consumption < 20 pW (limited by measurement). Multi-bit write operation (2 bits) is also demonstrated and verified over a time duration of 24 hours and most likely beyond. The cascaded 2nd order ring resonator CTM filter exhibited an improved ER of ~ 7.11 dB compared to the MZI and wavelength shifts of Δλnon-volatile = 0.041 nm (Δneff,non-volatile = 1.5 × 10-4) with similar pW-level dynamic power consumption as the MZI CTM. The ability to co-locate photonic computing elements and non-volatile memory provides an attractive path towards eliminating the von-Neumann bottleneck.

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“…As a comparison, MOSCAP-driven Si-MRMs can achieve a much larger capacitance density using ultra-thin high dielectric constant insulators such as HfO 2 . In addition, MOSCAP devices allow heterogeneous integration of more E-O efficient gate materials with Si waveguide such as III-V compound semiconductors and graphene [23][24][25][26][27][28][29][30] . In the past two decades, high-speed MOSCAP Si-MRMs, including heterogeneously integrated functional materials, have been demonstrated (Supplementary Information I) 7,10,[31][32][33][34][35][36][37] .…”

mentioning

confidence: 99%

Sub-Volt High-Speed Silicon MOSCAP Microring Modulator Driven by High Mobility Conductive Oxide

Wang,

Hsu,

Nujhat

et al. 2023

Preprint

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Low driving voltage (Vpp), high-speed silicon microring modulator plays a critical role in energy-efficient optical interconnect and optical computing systems owing to its ultra-compact footprint and capability for on-chip wavelength-division multiplexing. However, existing silicon microring modulators usually require more than 2 V of Vpp, which is limited by the relatively weak plasma dispersion effect of silicon and the small capacitance density of the reversed PN-junction. Here we present a highly efficient metal-oxide semiconductor capacitor (MOSCAP) microring modulator through heterogeneous integration between silicon photonics and titanium-doped indium oxide, which is a high-mobility transparent conductive oxide (TCO) material with a strong plasma dispersion effect. The device is co-fabricated by Intel's photonics fab and TCO patterning processes at Oregon State University, which exhibits a high electro-optic modulation efficiency of 117 pm/V with a low Vπ•L of 0.12 V•cm, and consequently can be driven by an extremely low Vpp of 0.8 V. At a 11 GHz modulation bandwidth where the modulator is limited by the high parasitic capacitance, we obtained 25 Gb/s clear eye diagrams with energy efficiency of 53 fJ/bit and demonstrated 35 Gb/s open eyes with a higher driving voltage. Further optimization of the device is expected to increase the modulation bandwidth up to 52 GHz that can encode data at 100 Gb/s for next-generation, energy-efficient optical communication and computation with sub-volt driving voltage without using any high voltage swing amplifier.

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Demonstration of a 17 × 25 Gb/s Heterogeneous III-V/Si DWDM Transmitter based on (De-) Interleaved Quantum Dot Optical Frequency Combs

Cited by 14 publications

References 50 publications

Energy efficient photonic memory based on electrically programmable embedded III-V/Si memristors: switches and filters

Energy efficient photonic memory based on electrically programmable embedded III-V/Si memristors: switches and filters

Ultra-Power-Efficient Electrically Programmable Photonic Memory on a Heterogeneous III-V/Si Optical Computing Platform

Sub-Volt High-Speed Silicon MOSCAP Microring Modulator Driven by High Mobility Conductive Oxide

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