Yuping Huang

Gallagher Associate Professor of Physics & Director of the Center for Quantum Science and Engineering

School: School of Engineering and Science

Department: Physics

Building: Burchard

Room: 618

Phone: (201) 216-5709

Fax: (201) 216-5638

Email: yhuang5@stevens.edu

Website

Education
  • PhD (2009) Michigan State University (Physics)
Research

My research interest is with developing advanced quantum technology and systems of practical relevance, with focus on mass-producible, highly-intergrated, turn-key, and room-temperature quantum devices.
The ongoing and near-term research topics our Laboratory for Quantum Enhanced Systems and Technology, include the following:

Quantum-Enhanced Biomedical Imaging
Quantum Processing on Chip
Quantum Solutions to Cyberthreats
Attojoule Photonics
Quantum remote sensing and metrology

For more details, please visit www.questlab.us.

Institutional Service
  • Center for Quantum Science and Engineering Chair
  • Graduate Program Member
  • SES Research Committee Member
  • Employee Awards Committee Member
  • Lecturer Search Member
  • Faculty Search Member
Professional Service
  • Editorial Board
  • Conference Committee
  • National Science Foundation Panel
Grants, Contracts, and Funds

Present:

"RAISE-EQuIP: A Chip-integrated Platform for Photon-Efficient Quantum Communications," NSF.
"EFRI ACQUIRE: Development of Heterogenous Platform for Chip-Based Quantum Information Applications," NSF.
"Collaborative Research: Parity-Time Symmetry and Anti-Symmetry in Quantum Optics," NSF
Innovation Systems Based Photonic Research, defense contract

Past:

"OP: Collaborative Research: Quantum Zeno Photonics on Chip," NSF (2015-2018).
"Persistent Maritime Quantum Key Distribution," ONR (2015-2018).
" MRI: Acquisition of cryogen‐free low‐temperature scanning‐probe spectroscopy system for nanophotonic and nanoelectronic device characterization," NSF

Selected Publications
Conference Proceeding
  1. Sua, Y. M.; Zhu, S.; Rehain, P.; Tafone, D.; Muthuswamy, B.; Ramanathan, J.; Dickson, I.; Huang, Y. (2020). Quantum 3D imaging through multiscattering media of 10 optical depth. Ocean Sensing and Monitoring XII (vol. 11420, pp. 1142009).
  2. Chen, J.; Ma, Z.; Sua, Y. M.; Huang, Y. (2019). Efficient quasi-phase-matched frequency conversion in a lithium niobate racetrack microresonator. Conference on Coherence and Quantum Optics (pp. W5A--11).
  3. Zhang, H.; Kumar, S.; Huang, Y. (2019). Mode-selective image upconversion through turbulence. Frontiers in Optics $+$ Laser Science APS/DLS. Frontiers in Optics $+$ Laser Science APS/DLS (pp. JW3A.46). Optical Society of America.
    http://www.osapublishing.org/abstract.cfm?URI=FiO-2019-JW3A.46.
  4. Rehain, P.; Sua, Y. M.; Zhu, S.; Dickson, I.; Muthuswamy, B.; Ramanathan, J.; Shahverdi, A.; Huang, Y. (2019). Noise-tolerant 3D Imaging. CLEO: Applications and Technology (pp. JTh5A--10).
Journal Article
  1. Fan, H.; Chen, J.; Zhao, Z.; Wen, J.; Huang, Y. (2020). Anti-Parity-Time Symmetry in Passive Nanophotonics. arXiv preprint arXiv:2003.11151.
  2. Chen, J.; Tang, C.; Ma, Z.; Li, Z.; Sua, Y. M.; Huang, Y. (2020). Efficient and highly tunable second-harmonic generation in Z-cut periodically poled lithium niobate nanowaveguides. Optics Letters (13 ed., vol. 45, pp. 3789--3792). Optical Society of America.
  3. Kumar, S.; Zhang, H.; Huang, Y. (2020). Large-scale Ising emulation with four body interaction and all-to-all connections. Communications Physics (1 ed., vol. 3, pp. 1--9). Nature Publishing Group.
  4. Rehain, P.; Sua, Y. M.; Zhu, S.; Dickson, I.; Muthuswamy, B.; Ramanathan, J.; Shahverdi, A.; Huang, Y. (2020). Noise-tolerant single photon sensitive three-dimensional imager. Nature Communications (1 ed., vol. 11, pp. 1--7). Nature Publishing Group.
  5. Chen, J.; Tang, C.; Ma, Z.; Li, Z.; Sua, Y. M.; Huang, Y. (2020). Ultra-efficient and highly-tunable second-harmonic generation in Z-cut periodically poled lithium niobate nanowaveguides. arXiv preprint arXiv:2004.02056.
  6. Zhang, H.; Kumar, S.; Huang, Y. (2020). A Super-resolution Optical Classifier with High Photon Efficiency. arXiv preprint arXiv:2006.16713.
  7. Huang, I.; Huang, Y. (2019). Counteracting quantum decoherence with optimized disorder in discrete-time quantum walks. Journal of Modern Optics (16 ed., vol. 66, pp. 1652-1657). Taylor & Francis.
    https://doi.org/10.1080/09500340.2019.1655598.
  8. Zhang, H.; Kumar, S.; Huang, Y. (2019). Mode Selective Image Upconversion over Turbulence. arXiv preprint arXiv:1907.08715.
  9. Huang, Y. (2019). Naturally Phase Matched Lithium Niobate Nanocircuits for Integrated Nonlinear Photonics. OSA Continuum (vol. 1, pp. 229). Hoboken: OSA.
    Dept. of Physic & Eng. Phys., Stevens Institute of Technology, 524 River St, Burchard Bldg, Rm 713.
  10. Tudor, S. F.; Chatterjee, R.; Nguyen, L.; Huang, Y. (2019). Quantum systems for Monte Carlo methods and applications to fractional stochastic processes. Physica A: Statistical Mechanics and its Applications (vol. 534, pp. 121901).
    http://www.sciencedirect.com/science/article/pii/S037843711931115X.
  11. Silver, M.; Huang, Y.; Langrock, C.; Fejer, M. M.; Kumar, P.; Kanter, G. S. (2019). Three-Signal Temporal-Mode Selective Upconversion Demultiplexing. IEEE Photonics Technology Letters (21 ed., vol. 31, pp. 1749--1752). IEEE.
  12. Chen, J.; Ma, Z.; Sua, Y. M.; Li, Z.; Tang, C.; Huang, Y. (2019). Ultra-efficient frequency conversion in quasi-phase-matched lithium niobate microrings. Optica (9 ed., vol. 6, pp. 1244--1245). Optical Society of America.
  13. Jin, M.; Chen, J.; Sua, Y. M.; Huang, Y. (2019). High-extinction electro-optic modulation on lithium niobate thin film. Opt. Lett. (5 ed., vol. 44, pp. 1265--1268). OSA.
    http://ol.osa.org/abstract.cfm?URI=ol-44-5-1265.
  14. Kumar, S.; Zhang, H.; Maruca, S.; Huang, Y. (2019). Mode-selective image upconversion. Opt. Lett. (1 ed., vol. 44, pp. 98--101). OSA.
    http://ol.osa.org/abstract.cfm?URI=ol-44-1-98.
  15. Shahverdi, A.; Sua, Y. M.; Dickson, I.; Garikapati, M.; Huang, Y. (2018). Mode selective up-conversion detection for LIDAR applications. Opt. Express (12 ed., vol. 26, pp. 15914--15923). OSA.
    http://www.opticsexpress.org/abstract.cfm?URI=oe-26-12-15914.
Courses

PEP 242: Modern Physics
PEP 201: Physics III
PEP 579: Nonlinear Optics
PEP 680: Quantum Optics