| Group Leader |  |
Group Leader: 潘义明,Dr. Assist. Prof. Yiming Pan
Address: 物质学院4号楼-107,Buidling 04-107, SPST, ShanghaiTech
Email: yiming.pan@shanghaitech.edu.cn
Phone: (+86) 19821952722
ORCID and Researcher ID: 0000-0003-4391-0226
Google Scholar:
https://scholar.google.co.il/citations?user=tDrBbUsAAAAJ&hl=en;
ResearchGate:
https://www.researchgate.net/profile/Yiming-Pan
CV:
| 2023.03 - Present ShanghaiTech University, China | Assistant Prof., PI |
2020. 09 - 2023. 03 Technion,Israel | Post Doc. (Instructor, Daniel Podolsky, Moti Segev) |
2018. 09 - 2020. 09 Weizmann,Israel | Post Doc. (Instructor:Yaron Silberberg, Nir Davidson) |
2016. 09 - 2018. 09 Tel Aviv University,Israel | Post Doc. (导师:Avraham Gover) |
2010.09 - 2016. 06 Nanjing University | Physics PhD.(导师:王伯根) |
2006. 09 - 2010. 06 Anhui University | Bachelor |
| Research Introduction | | Quantum and Strong Field |
1. Ultrafast, Strong-Field, and Quantum Light and Matter Interactions
Laser-Induced Dielectric Laser Acceleration(DLA) and Free-Electron Laser (FEL)
Photon-Induced Near-Field Electron Microscopy(PINEM)
Attosecond Dynamics Control, and Quantum Weak Measurements
2. Topological Photonics and Quantum Simulation
Laser Writing, Plasma-Induced Effectes, Topological Photonics in Waveguides
Ultrafast PINEM for Electron Synthesis Dimensions, Topological Floquet Time Crystals, Nonlinear Photon Time Crystals
Time-Modulated Momentum Band Gap Solitons, Subharmonic Generation, and Nonlinear Modulation Instablities
3. Condensed Matter and Field Theory
Chiral Transport in Weyl Semimetals, Transport Phenomena in Two-Dimensional Materials,
Weyl Semimetals
Quantum Anomalies in Periodically Driven Systems and the Callan-Harvey Mechanism
Light and Free Electrons (Big picture)
In the strong field and quantum domain, study the interaction between free electrons and light. The applied physics objective is to achieve controlled transfer of energy, momentum and information between electrons and light. The fundamental physics goal is to explore the underlying structure of electromagnetic interactions. • PS:We care about light and electron themselves,rather than materials。Materials only plays a role of third medium. • PS again:But we also cannot deny the 'phase matching' effect of suitable materials.
About goal and motivation of this group,three sentences to conclude:Goal: “Shaping electron with light, shaping light with electron.” — Ido Kaminer (Technion) 哲学: “潘兄会不会光就是电,电就是光?” “这你得问SHE!” — Zhaopin Chen (Technion) Principle: Free electron and photon can exchange energy, momentum, and even information at the quantum level. — Yiming Pan (ShanghaiTech) Research 1: (Theoretical)• Floquet engineering in optics and condensed matters Floquet engineering is a paradigm of tailoring and manipulating a system by a periodic drive.
• Momentum gaps (k-gaps) and energy-momentum gaps(ωk-gaps)
• Quantum anomalies in periodically driven systems (anomalies are not dangerous)
• Weak measurement and its experimental realizations Weak measurement can demonstrate the transition from quantum to classical. However, decoherence only leads to the statistics.
• Riemann Hypothesis in quantum physics.
. •Prompt engineering in daily life — Principle of using ChatGPT: Prompt: Now you are a physicist. You are both theoretical physicist andexperimentalist.You are very good at quantum mechanics,quantum optics,light and matter interactions, and condensedmatter physics.You can clearly explain the history anddefinitions of many concepts in quantum physics and optics.You can derive toy models to explain many physical phenomenaand effects. You are also good at simulation software such asMathematica,and COMSOL. You can find out the reals scientificproblem and do a great research. You are my supervisor, you canteach and guide to do a real science. Do not reply instantly - ifyou have any questions about this prompt, ask me. If you areready, ask me to give you the text. Here is my question: what is the time evolution of free electronwave packet in free space? Let's think step by step. Three principles: Principle 1: be very specific in yourinstructions. Principle 2: is to ask GPT-3 to break itswork into small chunks. Principle 3: ask GPT-3 to check and improve its own output. Research 2: (Experimental) • Ultrafast electron generation and manipulation, and strong-field electron photon coupling at discontinuity. • Design an ultrafast photoelectron gun and realizemuti-photon free-free transition for low-energy free electrons. • Floquet simulators: optics, microwave, sounds, atoms and free electrons. In a word, to achieve and detect quantum entanglement of ultrafast electrons and ultrafast photons
|
| Teaching Philosophy | |
Equally access to education to all individualswithout discrimination (in Chinese, “有教无类”)
To educate college students and high school kids:The first principle for me is to admit my stupidity in front of them.
To teach graduate students and postdocs:
My job is to support them in achieving success in science and technology.
Contribute to Zhihu community related to Physics
https://www.zhihu.com/people/yimingpan-1204/columns
To teach the public:
The most critical aspect of disseminating information to the public in determining: What is NOT science!
| Members | |
In Group:
Xiangting Tan, 谭湘婷 MS student
Wenhao Shen, 沈文淏 Research assistant
We need:
1-2 Post Doc.; 1 Research assistant(Experiment-oriented)
2-4 Phd Student; 2-4 MSc student
| Publications | |
Parts of representative papers:
Zhaopin Chen, Bin Zhang, Yiming Pan*, Michael Krueger, Quantum wavefunction reconstruction by free-electron spectral shearing interferometry. arXiv:2210.16312 (2022); Accepted by Science Advances (2023)
Yiming Pan†*, Moshe-Ishay Cohen, Mordechai Segev, Superluminal k-gap solitons in photonic time-crystals with Kerr nonlinearity. CLEO 2022, PRL 130, 233801 (2023).
Pan, Y.†*, et al. Demonstration of weak measurements, projective measurements, and quantum-to-classical transitions in ultrafast free electron-photon interactions. Accepted by Light: Science & Applications (2023)
Pan, Y. .†*, et al. Floquet gauge anomaly inflow and arbitrary fractional charge in periodically-driven topological/normal insulator heterostructures. PRL 130, 223403 (2023).
Q. Cheng, Y. Pan*, et al. Asymmetric topological pumping in nonparaxial photonics. Nat. Commun. 10.1038 (2022)
B. Wang,…, Y. Pan*, Observation of Photonic Topological Floquet time crystals. Laser & Photon. Rev, 10.1002/lpor.202100469 (2022)
Y. Pan†*, and A. Gover. Beyond Fermi's Golden Rule in Free-Electron Quantum Electrodynamics: Acceleration/Radiation Correspondence. New Journal of Physics 23 (6), 063070 (2021)
Pan, Y.†*, et al., Weak-to-strong transition of quantum measurement in a trapped-ion system. Nat. Phys. 16(12), 1206-1210 (2020)
Yiming Pan†*, et al., Anomalous Photon-induced Near-field Electron Microscopy. PRL 122,183204 (2019)
Q. Cheng†, Y. Pan†*, et al. Observation of anomalous π modes in photonic Floquet engineering. PRL 122.173901 (2019)
A. Gover, Y. Pan*. Dimension-dependent stimulated radiative interaction of a single electron quantum wavepacket. Phys. Lett. A 382.23 (2018): 1550-1555
Z. Yu†, Z. Ong†, Y. Pan†, et al. Realization of Room-Temperature Phonon-limited Carrier Transport in Monolayer MoS2 by Dielectric and Carrier Screening. Adv. Mater. 28, no. 3 (2016): 547-552.
Q. Cheng†, Y. Pan†, et al. Topologically protected interface mode in plasmonic waveguide arrays. Laser & Photon. Rev. 10.1002/lpor.201400462(2015)
M. Qian, Y. Pan, et al. Tunable, Ultralow-Power Switching in Memristive Devices Enabled by a Heterogeneous Graphene–Oxide Interface. Adv. Mater. 26, 3275-3281 (2014)
Z. Yu†, Y. Pan†, et al. Towards Intrinsic Charge Transport in Monolayer Molybdenum Disulfide by Defect and Interface Engineering. Nat. Commun. 5, 5290 (2014)
PUBLICATIONS
2023
Hongwei Wu, Yiming Pan, et al. Hearing dynamical Floquet-Thouless pump of sound pulse. preprinted on Research Square (2023).
Yiming Pan, Ruoyu Yin. Constructing Berry-Maxwell equations with Lorentz invariance and Gauss' law of Weyl monopoles in 4D energy-momentum space. arXiv:2308.00612 (2023).
Zhaopin Chen, Bin Zhang, Yiming Pan*, Michael Krueger, Quantum wavefunction reconstruction by free-electron spectral shearing interferometry. arXiv:2210.16312 (2022); Accepted by Science Advances (2023)
Yiming Pan†, Moshe-Ishay Cohen†, Mordechai Segev, Superluminal k-gap solitons in photonic time-crystals with Kerr nonlinearity. CLEO 2022, PRL 130, 233801 (2023)
Pan, Y.*, Chen, Z.*, Wang, B., & Poem, E. Photonic π-mode anomaly in (1+1) dimensional periodically driven topological/normal insulator heterostructures. arXiv:2010.05688 (2020), PRL 130, 223403 (2023).
Pan, Y. *, Cohen, E.*, et al. Demonstration of weak measurement, projective measurement, and quantum-to-classical transitions in electron-photon interactions. arXiv:1910.11685 (2020); accepted by Light Science & Applications (2023).
2022
Wang, B., Quan, J., Han, J., Shen, X.*, Wu, H.*, and Pan, Y.*, Observation of Photonic Topological Floquet time crystals. Laser & Photon. Rev, 10.1002/lpor.202100469 (2022).
Qingqing Cheng, Huaiqiang Wang, Yongguan Ke, Tao Chen, Ye Yu, Yuri S. Kivshar*, Chaohong Lee*, and Yiming Pan*, Asymmetric topological pumping in nonparaxial photonics. Nature Communications. https://doi.org/10.1038/s41467-021-27773 (2022).
2021
Ang Li, Yiming Pan, Philip Dienstbier, and Peter Hommelhoff, Quantum interference visibility spectroscopy in two-color photoemission from tungsten needle tips. Phys. Rev. Lett. 126, 137403 (2021).
Yiming Pan†*, and Avraham Gover. Beyond Fermi's Golden Rule in Free-Electron Quantum Electrodynamics: Acceleration/Radiation Correspondence. New Journal of Physics 23 (6), 063070 (2021).
2020
Yiming Pan†*, Bing Wang, Time-crystalline phases and period-doubling oscillations in one-dimensional Floquet topological insulators. Physical Review Research, 2(4), 043239 (2020).
Pan, Y.†*, Zhang, J., Cohen, E., Wu, C.W., Chen, P.X. and Davidson, N., Weak-to-strong transition of quantum measurement in a trapped-ion system. Nature Physics, 16(12), 1206-1210 (2020).
2019
Chen, T., Yu, Y., Song, Y., Yu, D., Ye, H., Xie, J., Shen, X., Pan, Y. and Cheng, Q., 2019. Distinguishing the topological zero mode and Tamm mode in a microwave waveguide array. Annalen der Physik, 531(12), p.1900347.
Ying Yang, Yiming Pan*. Engineering zero modes, Fano resonance and Tamm surface states of 'bound states in the gapped continuum'. Optics Express 27 (23), 32900-32911 (2019).
Q. Q. Cheng†, Yiming Pan†*, Huaiqiang Wang†, et al. Observation of anomalous π modes in photonic Floquet engineering. PhysRevLett.122.173901 (2019).
Yiming Pan†*, Bin Zhang†, and Avraham Gover. Anomalous Photon-induced Near-field Electron Microscopy. PhysRevLett.122.183204 (2019).
Yiming Pan†*, and Avraham Gover. Spontaneous and Stimulated Emissions of Quantum Free-Electron Wavepackets - QED Analysis. PhysRevA.99.052107 (2019).
2018
Yiming Pan†*, and Avraham Gover. Spontaneous and Stimulated Radiative emission of Modulated Free-Electron Quantum wavepackets-Semiclassical Analysis. Journal of Physics Communications 2.11 (2018): 115026.
Cheng, Q., Chen, T., Yu, D., ... & Pan, Y*. Flexibly designed spoof surface plasmon waveguide array for topological zero-mode realization. Optics Express, 26(24), 31636-31647 (2018).
Gover, Avraham, Yiming Pan*. Dimension-dependent stimulated radiative interaction of a single electron quantum wavepacket. Physics Letters A 382.23 (2018): 1550-1555.
2017
Xing-Chen Pan, Yiming Pan, et al. Carrier balance and linear magnetoresistance in type-II Weyl semimetal WTe 2. Frontiers of Physics 12, 3 (2017): 127203.
2016
H.Q.Wang, Lubing Shao, Yiming Pan, et al. Flux-driven quantum phase transitions in two-leg Kitaev ladder systems. Physics Letters A 380, 46 (2016): 3936-3941.
Erfu Liu, Mingsheng Long, Junwen Zeng, Wei Luo, Yaojia Wang, Yiming Pan, et al. High responsively phototransistors based on few-layer ReS2 for weak signal detection. Advanced Functional Materials 26, 12 (2016): 1938-1944.
Wang, Yaojia, Erfu Liu, Huimei Liu, Yiming Pan, et al. Gate-tunable negative longitudinal magnetoresistance in the predicted type-II Weyl semimetal WTe 2. Nature Communications 7 (2016): 13142.
Zhihao Yu†, Zhun-Yong Ong†, Yiming Pan†, et al. Realization of Room-Temperature Phonon-limited Carrier Transport in Monolayer MoS2 by Dielectric and Carrier Screening. Advanced Materials 28, 3 (2016): 547-552.
2015
Q. Q. Cheng†, Yiming Pan†, et al. Topologically protected interface mode in plasmonic waveguide arrays. Laser & Photon. Rev. doi: 10.1002/lpor.201400462(2015)
Daowei He†, Yiming Pan†, et al. Tunable Van der Waals heterojunctions with hybrid organic/inorganic semiconductors. Applied Physics Letters, 107(18), p.183103 (2015)
Miao Wang, Xiaojuan Lian, Yiming Pan, et al. A selector device based on graphene-oxide heterostructures for memristercrossbar application. Appl. Phys. A 120:403-407 (2015)
Yang Cui†, Run Xin†, Zhihao Yu†, Yiming Pan, et al. High-Performance Monolayer WS2 Field-effect Transistors on High-κDielectrics. Adv. Mater. doi:10.1002/adma.201502222 (2015)
2014
Zhihao Yu†, Yiming Pan†, et al. Towards Intrinsic Charge Transport in Monolayer Molybdenum Disulfide by Defect and Interface Engineering. Nat. Commun. 5, 5290 (2014)
Min Qian, Yiming Pan, et al. Tunable, Ultralow-Power Switching in Memristive Devices Enabled by a Heterogeneous Graphene–Oxide Interface. Adv. Mater. 26, 3275–3281 (2014)
Xiaxin Ding, Yiming Pan, et al. Strong and nonmonotonic temperature dependence of Hall coefficient in superconducting KxFe2−ySe2 single crystals. Phys. Rev. B 89, 224515 (2014)
Enming Shang, Yiming Pan, et al. Detection of Majorana fermions in an Aharonov-Bohm interferometer. Chinese Phys. B 23, 057201 (2014)
H.Q.Wang, R.Wang, Yiming Pan, et al. Entanglement spectrum of topological Weyl semimetal. EPL 107, 40007 (2014)
OTHERS
Yiming Pan. How to measure the canonical commutation relation [x, p]=iℏ in quantum mechanics with weak measurement? arXiv:1702.08518 (2017)
Yiming Pan, et al. Mass classification and manipulation of zero modes in one-dimensional Dirac systems. arXiv: 1407.3874v1 (2014)