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Mingda Li
Mingda Li
Associate Professor
Nuclear Science and Engineering
Lab Website
Education
  • PhD, Department of Nuclear Science and Engineering, Massachusetts Institute of Technology, 2015.
  • BS, Department of Engineering Physics, Tsinghua University, China, 2009.
Appointment
  • Summer researcher, MIT Energy Initiative, 2015.
  • Postdoctoral Associate, Department of Mechanical Engineering, MIT, 2015-2017.
Awards
  • Junior Bose Award, MIT School of Engineering, 2023
  • U.S. Department of Energy (DOE) Early Career Research Program Award, 2021
  • Ruth and Joel Spira Award for Distinguished Teaching, MIT School of Engineering, 2021

Quantum Measurement Group Website: qm.mit.edu

 

The research focus of Mingda and his group (Quantum Measurement Group) is to design novel materials characterization methods and to augment existing characterization methods to probe key properties of quantum materials that were either considered not measurable or not readily measurable with existing technique and analysis methods.

 

Materials characterization is essential for materials science. The birth of a new characterization method, such as X-ray diffraction (XRD), photoemission spectroscopy (PES), or inleastic neutron scattering (INS), all comes with great discoveries. However, the finite type of probe particles (e.g., photons, electrons, or neutrons) in one or more spaces (r, k, E, t) restricts the combination of measurable correlation functions, and even so, it is not always easy to interpret the experimental data.

 

To tackle the challenge, we take an integrated quantum theory, machine-learning, unconventional use of spectroscopies, and new architecture design approach: Quantum theory lays the foundation on measurable correlation functions, machine-learning aids to uncover hidden properties buried in data, unconventional use of neutron, x-ray, and electron spectra empowers existing techniques to a broader scope, and an integration of all these into new architecture can enable the detection of materials’ properties that evade experimental detection.

Selected Publications

  • NT Hung, R Okabe, A Chotrattanapituk and M Li, “Universal Ensemble-Embedding Graph Neural Network for Direct Prediction of Optical Spectra from Crystal Structures”
    Advanced Materials 36, 2409175 (2024)
  • M Mandal, A Chotrattanapituk, K Woller, LJ Wu, H Xu, NT Hung, N Mao, R Okabe, A Boonkird, T Nguyen, NC Drucker, XM Chen, T Momiki, J Li, J Kong, Y Zhu, and M Li, “Precise Fermi-level engineering in a topological Weyl semimetal via fast ion implantation”
    Applied Physics Review 11, 021429 (2024)
  • R Okabe, A Chotrattanapituk, A Boonkird, N Andrejevic, X Fu, TS Jaakkola, Q Song, T Nguyen, NC Drucker, S Mu, B Liao, Y Cheng, and M Li, “Virtual Node Graph Neural Network for Full Phonon Prediction”
    Nature Computational Science 4, 522 (2024)
  • M Cheng, R Okabe, A Chotrattanapituk and M Li, “Machine Learning Detection of Majorana Zero Modes from Zero Bias Peak Measurements”
    Matter 7, 2507 (2024)
  • R Okabe, S Xue, J Vavrek, J Yu, R Pavlovsky, V Negut, B Quiter, J Cates, T Liu, B Forget, S Jegelka, G Kohse, L-W Hu and M Li, “Tetris-inspired detector with neural network for radiation mapping”
    Nature Communications 15, 3061 (2024)
  • NC Drucker, T Nguyen, F Han, P Siriviboon, X Luo, N Andrejevic, Z Zhu, G Bednik, QT Nguyen, Z Chen, LK Nguyen, T Liu, TJ Williams, MB Stone, AI Kolesnikov, S Chi, J Fernandez-Baca, C Nelson, A Alatas, T Hogan, AA Puretzky, S Huang, Y Yue and M Li “Topology stabilized fluctuations in a magnetic nodal semimetal”
    Nature Communications 14, 5182 (2023)
  • Z Chen, X Shen, N Andrejevic, T Liu, D Luo, T Nguyen, NC Drucker, M Kozina, Q Song, C Hua, G Chen, X Wang, J Kong and M Li
    “Panoramic Mapping of Phonon Transport from Ultrafast Electron Diffraction and Machine Learning”
    Advanced Materials 35, 2206997 (2023)
  • N Andrejevic, J Andrejevic, BA Bernevig, N Regnault, F Han, G Fabbris, T Nguyen, NC Drucker, CH Rycroft, and M Li
    “Machine Learning Spectral Indicators of Topology”
    Advanced Materials 34, 202204113 (2022)
  • N Andrejevic, Z. Chen, T Nguyen, L Fan, H Heiberger, LJ Zhou, YF Zhao, CZ Chang, A Grutter, and M Li
    “Elucidating Proximity Magnetism through Polarized Neutron Reflectometry and Machine Learning”
    Appl. Phys. Rev. 9, 011421 (2022)
  • T Nguyen, N Andrejevic, HC Po, Y Tsurimaki, NC Drucker, A Alatas, EE Alp, BM Leu, A Cunsolo, Y Cai, L Wu, JA Garlow, Y Zhu, H Lu, AC Gossard, AA Puretzky, DB Geohegan, S Huang and M Li
    “Signature of Many-Body Localization of Phonons in Strongly Disordered Superlattices”
    Nano Lett. 21, 7419 (2021)
  • Z Chen, N Andrejevic† NC Drucker, T Nguyen, RP Xian, T Smidt, Y Wang, R Ernstorfer, DA Tennant, M Chan, and M Li
    “Machine Learning on Neutron and X-Ray Scattering and Spectroscopies”
    Chem. Phys. Rev. 2, 031301 (2021)
  • Z Chen, N. Andrejevic, T Smidt, Z Ding, Q Xu, YT Chi, QT Nguyen, A Alatas, J Kong and M Li
    “Direct Prediction of Phonon Density of States with Euclidean Neural Networks”
    Advanced Science 8, 2004214 (2021)
  • F Han, N Andrejevic, T Nguyen, V Kozii, QT Nguyen, T Hogan, Z Ding, R Pablo-Pedro, S Parjan, B Skinner, A Alatas, EE Alp, S Chi, J Fernandez-Baca, S Huang, L Fu and M Li
    “Quantized Thermoelectric Hall Effect Induces Giant Power Factor in a Topological Semimetal”
    Nature Communications 11, 6167 (2020)
  • T Nguyen, F Han, N Andrejevic, R Pablo-Pedro, A Apte, Y Tsurimaki, Z Ding, K Zhang, A Alatas, EE Alp, S Chi, J Fernandez-Baca, M Matsuda, DA Tennant, Y Zhao, Z Xu, JW Lynn, S Huang and M Li
    “Topological Singularity Induced Chiral Kohn Anomaly in a Weyl Semimetal”
    Phys. Rev. Lett. 124, 236401 (2020)

Full list of publications can be found here.