People: Christie Chiu

Harvard
cchiu@fas.harvard.edu
(617) 495-9875
Room Jefferson-355
Oxford Street
Cambridge, MA 02139
Greiner
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Graduate Student
Publications
  1. G. Ji, M. Xu, L. Kendrick, C. Chiu, D. Greif, A. Bohrdt, F. Grusdt, E. Demler, M. Lebrat, M. Greiner, and J.C. Bruggenjurgen. Coupling a Mobile Hole to an Antiferromagnetic Spin Backgroung: Transient Dynamics of a Magnetic Polaron. Phys. Rev. X , 11(021022), April 2021.
  2. A. Bohrdt, C. Chiu, G. Ji, M. Xu, D. Greif, M. Greiner, E. Demler, Classifying snapshots of the doped Hubbard model with machine learning. Nature Physics July 2019.
  3. C. Chiu Quantum simulation of the Hubbard model. Harvard University, 2019.
  4. C. Chiu, G. Ji, A. Bohrdt, M. Xu, M. Knap, E. Demler, F. Grusdt, M. Greiner, D. Greif, String patterns in the doped Hubbard model. Science July 2019.
  5. F. Grusdt, M. Kanasz-Nagy, A. Bohrdt, C. Chiu, G. Ji, M. Greiner, D. Greif, E. Demler, Parton theory of magnetic polarons: Mesonic resonances and signatures in dynamics. Physical Review X, 8(011046), 2018.
  6. C. Chiu, G. Ji, A. Mazurenko, D. Greif, M. Greiner, Quantum state engineering of a Hubbard system with ultracold fermions. Phys. Rev. Lett. , 20(243201), June 2018.
  7. A. Mazurenko, C. Chiu, G. Ji, M. Parsons, M. Kanasz-Nagy, R. Schmidt, F. Grusdt, E. Demler, D. Greif, M. Greiner, A cold-atom Fermi-Hubbard antiferromagnet. Nature, 545, May 2017.
  8. M. Parsons, A. Mazurenko, C. Chiu, S. Blatt, F. Huber, G. Ji, M. Greiner, and D. Greif. Site-Resolved Imaging of a Fermionic Mott Insulator. Science, 351:953, 2016.
  9. M. Parsons, A. Mazurenko, C. Chiu, G. Ji, D. Greif, M. Greiner, Site-resolved measurement of the spin-correlation function in the Fermi-Hubbard model. Science, 353(6305), September 2016.
  10. M. Parsons, F. Huber, A. Mazurenko, C. Chiu, W. Setiawan, K. Wooley Brown, S. Blatt, M. Greiner, and W. Siawan. Site-Resolved Imaging of Fermion 6Li in an Optical Lattice. Phys. Rev. Lett, 114:213002, 2015.
News
Thu May 2, 2019

String patterns in the doped Hubbard model

Understanding strongly correlated quantum many-body states is one of the most thought-provoking challenges in modern research. For example, the Hubbard model, describing strongly correlated electrons in solids, still contains fundamental open questions on its phase diagram. In this work we realize the Hubbard Hamiltonian and search for specific patterns within many individual images of realizations...
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News type:
Research Highlights
Thu June 14, 2018

Quantum state engineering of a Hubbard system with ultracold fermions

Accessing new regimes in quantum simulation requires the development of new techniques for quantum state preparation. We demonstrate the quantum state engineering of a strongly correlated many-body state of the two-component repulsive Fermi-Hubbard model on a square lattice. Our scheme makes use of an ultralow entropy doublon band insulator created through entropy redistribution. After isolating...
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News type:
Research Highlights