Peihao Huang Assistant Researcher
email: null
Office:Innovation Park Bld. 10, Room 409
Research Field:Solid State Quantum Theory, Condensed Matter Physics
Essential Information
Name: Peihao Huang
Position: Assistant Researcher (PI)
Highest Degree:PHD
Telephone(office):N/A
Office:Innovation Park Bld. 10, Room 409
Research Field:Solid State Quantum Theory, Condensed Matter Physics
Peihao received B.Sc. (2006) and Ph.D. (2011) in Physics from Shanghai Jiao Tong University. He has held Postdoc positions at University at Buffalo, California State University, and Joint Quantum Institute of National Institute of Standards and Technology and University of Maryland; and Joined Southern University of Science and Technology in 2018. Peihao’s current research interest is on the theory of quantum properties in nanostructures.
Email contact: huangphATsustech.edu.cn; or phhuang.cmpATgmail.com;
Educational Background
2006.09-2011.07 Ph. D. in Condensed Matter Physics, Shanghai Jiao Tong University, China
2002.09-2006.07 B. Sc. in Applied Physics, Shanghai Jiao Tong University, China
Working Experience
2015.09-2018.06, Postdoctoral Researcher, Joint Quantum Institute, National Institute of Standards and Technology and University of Maryland
2014.09-2015.08, Postdoctoral Researcher, Department of Physics, California State University Northridge
2011.11-2014.08, Postdoctoral Researcher, Department of Physics, University at Buffalo
Honors and Awards
Papers and Patents
1. P. Huang and X. Hu, “Electric-dipole induced resonance and decoherence of a dressed spin in a quantum dot”, arXiv:2103.05817, submitted;
2. P. Huang and X. Hu, “Fast spin-valley-based quantum gates in Si with micromagnets”, accepted by NPJ Quantum Inf. (2021);
3. P. Huang, “Dephasing and manipulation of two-electron spins in quantum dots for spin-based quantum computing”, Adv. Quantum Technol. (2021), DOI: 10.1002/qute.202100018;
4. X. Cao, C. Jiang, P. Huang*, “Non-Markovian dynamics of the driven spin-boson model”, New J. Phys. 23, 093044 (2021);
5. X. Zhang, Y. Zhou, R.-Z. Hu, R.-L. Ma, M. Ni, K. Wang, G. Luo, G. Cao, G.-L. Wang, P. Huang, X. Hu, H.-W. Jiang, H.-O. Li, G.-C. Guo, and G.-P. Guo, Controlling Synthetic Spin-Orbit Coupling in a Silicon Quantum Dot with Magnetic Field, Phys. Rev. Appl. 15, 044042 (2021).
6. B. Sarabi, P. Huang, and N. M. Zimmerman, “Prospective two orders of magnitude enhancement in direct magnetic coupling of a single-atom spin to a circuit resonator”, Phys. Rev. Appl. 11, 014001 (2019);
7. P. Huang, N. M. Zimmerman, G. W. Bryant, “Spin decoherence in a two-qubit CPHASE gate: the critical role of tunneling noise”, NPJ Quantum Inf. 4, 62 (2018);
8. P. Huang, G. W. Bryant, “Spin relaxation of a donor electron coupled to interface states”, Phys. Rev. B 98, 195307 (2018);
9. N.M. Zimmerman, P. Huang, and D. Culcer, “Valley Phase, Interface Roughness and Voltage Control, and Coherent Manipulation in Si Quantum Dots”, Nano Lett. 17, 44614465 (2017);
10. X. Zhao, P. Huang and X. Hu, “Doppler effect induced spin relaxation boom”, Sci. Rep. 6, 23169 (2016);
11. P. Huang and X. Hu, “Spin relaxation in a Si quantum dot due to spin-valley mixing”, Phys. Rev. B 90, 235315 (2014);
12. J. Jing, P. Huang and X. Hu, “Decoherence of an electrically driven spin qubit”, Phys. Rev. A 90, 022118 (2014);
13. P. Huang and X. Hu, “Spin relaxation due to charge noise”, Phys. Rev. B 89, 195302 (2014);
14. P. Huang and X. Hu, “Spin qubit relaxation in a moving quantum dot”, Phys. Rev. B 88, 075301 (2013);
15. P. Huang and H. Zheng, “Effect of bath temperature on the quantum decoherence”, Chem. Phys. Lett. 500, 256-262 (2010);
Presentations:
1. P. Huang, “Spin-valley-based quantum gates in silicon”, Silicon Quantum Electronics Workshop 2021, October 25, 2021.
2. P. Huang and X. Hu, “Fast spin-valley-based quantum gates in Si with micromagnets”, APS March Meeting, March 18, 2021.
3. P. Huang, “Spin decoherence in a single or double quantum dot”, Silicon Quantum Electronics Workshop 2019, San Sebastian, Spain, October 14, 2019.
4. P. Huang and X. Hu, “Spin decoherence in a quantum dot due to micro-magnets”, APS March Meeting, Boston, MA, March 4, 2019.
5. P. Huang, N. M. Zimmerman, G. W. Bryant, “Critical role of tunneling noise on spin decoherence in a two-qubit gate”, APS March Meeting, Los Angeles, LA, March 6, 2018.
6. P. Huang and G.W. Bryant “Electrical control of spin qubit shuttling between a donor and a quantum dot”, APS March Meeting, New Orleans, LA, March 16, 2017.
7. B. Sarabi, P. Huang, N.M. Zimmerman, “Prospective enhancement in the spin-to-photon magnetic coupling rate using tri-layer lumped element superconducting resonators”, APS March Meeting, New Orleans, LA, March 16, 2017.
8. P. Huang, G.W. Bryant, “Decoherence of two electron spin qubit in Si double quantum dot with g-factor modulations”, APS March Meeting, Baltimore, MD, March 16, 2016.
9. P. Huang, “Spin relaxation in a quantum dot and its impact on spin-based quantum computing”, Division Seminar, National Institute of Standards and Technology, Gaithersburg, MD, April 22, 2015.
10. P. Huang and X. Hu, “Spin Relaxation due to Charge Noise in Si Quantum Dot with Valley Splitting”, APS March Meeting, Denver, CO. March 5, 2014.
11. P. Huang and X. Hu, “Spin qubit relaxation in a moving quantum dot”, APS March Meeting, Baltimore, MD. March 19, 2013.
12. P. Huang and X. Hu, “Spin qubit relaxation due to charge noise”, APS March Meeting, Baltimore, MD. March 19, 2013.
13. P. Huang and X. Hu, “Spin qubit relaxation in a moving quantum dot”, Departmental Seminar, University at Buffalo, Buffalo, NY, October 9, 2012.
14. P. Huang and H. Zheng, “Effect of bath temperature on the quantum decoherence”, 16th National Conference on Theoretical Condensed Matter and statistical physics, Jilin, Changchun, China. August 22, 2010.
Undertaking project
Service for Academic Societies