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Xiaoxi Wang
Xiaoxi Wang
Research Scientist, Intel Labs
Verified email at ucsd.edu
Title
Cited by
Cited by
Year
Silicon photonic entangled photon-pair and heralded single photon generation with CAR > 12,000 and g(2)(0) < 0.006
C Ma, X Wang, VA Anant, AD Beyer, MD Shaw, S Mookherjea
Optics Express 25 (26), 32995-33006, 2017
1332017
Achieving beyond-100-GHz large-signal modulation bandwidth in hybrid silicon photonics Mach Zehnder modulators using thin film lithium niobate
X Wang, PO Weigel, J Zhao, M Ruesing, S Mookherjea
APL Photonics 4 (9), 2019
1192019
A 1.23 pJ/b 2.5 Gb/s monolithically integrated optical carrier-injection ring modulator and all-digital driver circuit in commercial 45nm SOI
BR Moss, C Sun, M Georgas, J Shainline, JS Orcutt, JC Leu, M Wade, ...
2013 IEEE International Solid-State Circuits Conference Digest of Technical …, 2013
482013
110 GHz, 110 mW Hybrid Silicon-Lithium Niobate Mach-Zehnder Modulator
F Valdez, V Mere, X Wang, N Boynton, TA Friedmann, S Arterburn, ...
arXiv:2210.14785, 2022
202022
Wide-range and fast thermally-tunable silicon photonic microring resonators using the junction field effect
X Wang, A Lentine, C DeRose, AL Starbuck, D Trotter, A Pomerene, ...
Optics express 24 (20), 23081-23093, 2016
192016
A Modular Fabrication Process for Thin-film Lithium Niobate Modulators with Silicon Photonics
V Mere, F Valdez, X Wang, S Mookherjea
JPhys Photonics 4, 2022
162022
Photon pair generation using a silicon photonic hybrid laser
X Wang, C Ma, R Kumar, P Doussiere, R Jones, H Rong, S Mookherjea
APL Photonics 3 (10), 2018
142018
Integrated O-and C-band silicon-lithium niobate Mach-Zehnder modulators with 100 GHz bandwidth, low voltage, and low loss
F Valdez, V Mere, X Wang, S Mookherjea
Optics Express 31 (4), 5273-5289, 2023
122023
Oscilloscopic Capture of Greater-than-100 GHz, Ultra-low Power Optical Waveforms Enabled by Integrated Electro-Optic Devices
X Wang, BA Korzh, PO Weigel, DJ Nemchick, BJ Drouin, W Becker, ...
Journal of Lightwave Technology, 2019
122019
A single-chip high-speed silicon photonic transmitter with integrated laser and micro-ring modulator
X Wu, R Kumar, D Huang, C Ma, GL Su, X Wang, S Liu, H Rong
2023 IEEE Silicon Photonics Conference (SiPhotonics), 1-2, 2023
102023
Performance comparisons between semiconductor and fiber amplifier gain assistance in a recirculating frequency shifter
X Wang, S Mookherjea
Optics Letters 43 (5), 1011-1014, 2018
102018
Photon Pair Generation Using Silicon Photonic Microring and Hybrid Laser
X Wang, C Ma, R Kumar, P Doussiere, R Jones, H Rong, S Mookherjea
CLEO: Applications and Technology, JTh5C. 6, 2017
92017
Compact High-extinction-ratio Silicon Photonic Variable Optical Attenuators (VOAs)
X Wang, S Mookherjea
CLEO: Science and Innovations, SW1N. 7, 2017
92017
Fast circuit modeling of heat transfer in photonic integrated circuits
X Wang, S Mookherjea
CLEO: Science and Innovations, JW2A. 141, 2017
82017
Compact silicon photonic resonance-sssisted variable optical attenuator
X Wang, R Aguinaldo, A Lentine, C DeRose, AL Starbuck, D Trotter, ...
Optics Express 24 (24), 27600-27613, 2016
82016
Progress towards a widely usable integrated silicon photonic photon-pair source
C Ma, X Wang, S Mookherjea
OSA Continuum 3 (6), 1398-1407, 2020
62020
Integrated thin-silicon passive components for hybrid silicon-lithium niobate photonics
X Wang, F Valdez, V Mere, S Mookherjea
Optics Continuum 1 (10), 2233-2244, 2022
52022
Photon-pair and heralded single photon generation initiated by a fraction of a 10 Gbps data stream
SM Chaoxuan Ma, Xiaoxi Wang
Optics Express 26 (18), 22904-22915, 2018
52018
Monolithic Integration of 110 GHz Thin-Film Lithium Niobate Modulator and High-Q Silicon Microring Resonator for Photon-Pair Generation
X Wang, F Valdez, V Mere, S Mookherjea
CLEO, 2022
32022
Oscilloscopic capture of 100 GHz modulated optical waveforms at femtowatt power levels
X Wang, BA Korzh, PO Weigel, DJ Nemchick, BJ Drouin, A Fung, ...
2019 Optical Fiber Communications Conference and Exhibition (OFC), 1-3, 2019
32019
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