Faculty

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  • Name: Yu, Jianghao
  • Title: Professor
  • Office: 321
  • Fax: 010-62551290
  • Highest Education: Ph.D.
  • Phone: 62551799
  • Email: jhyu@itp.ac.cn

    Education and Appointments:

  • Working experiences

    2017.12 -

    Institute of Theoretical Physics, Chinese Academy of Science, Assoicate Professor, Professor

    2015.09 - 2017.11

    University of Massachusetts at Amherst, ACFI, Postdoc research associate

    2012.09 - 2015.08

    University of Texas at Austin, Weinberg Theory group, Postdoc fellow


    Educations

    2007.09 - 2012.08

    Michigan State University, Dept. of Physics and Astronomy, Ph.D.

    2004.09 - 2007.08

    Peking University, College of Physics, Theoretical Physics, M.Sc.

    2000.09 - 2004.07

    Northeast Normal University, Dept. of Physics, B.Sc.


    My research area and research focus

    My research area is theoretical particle physics and particle cosmology, focusing on origin of the Higgs mass and neutrino masses, origin of matter and dark matter, and effective field theories.

    Recently I am working on naturalness and shape of Higgs potential, standard model effective field theory and chiral Lagrangian, electroweak phase transition and baryogenesis, dark matter and cosmological signatures.

    If you are interested in my research, please visit my personal website: https://yu-jianghao.github.io

    You can also find my updated publications through INSPIRE-HEP: https://inspirehep.net/authors/1066117


    My recent research interests

    (1) Origin of Higgs mass and neutrino masses: nature of Higgs boson and Higgs potential, electroweak phase transition and gravitational wave, neutral naturalness and composite Higgs;

    (2) Effective field theory framework: standard model effective field theory, chiral effective field theories for composite Higgs, electroweak and QCD chiral Lagrangian;

    (3) Origin of matter and dark matter: electroweak baryogenesis and leptogenesis, non-thermal history of dark matter and cosmological implications, sterile neutrino and axion;

    (4) Energy and intensity frontiers: collider phenomenology, dark matter direct detection and coherent neutrino elastic scattering, neutrinoless double bete decay experiments.

    Research Direction:

  • Effective field theory, Origin of masses and origin of matter, Higgs physics and electroweak phase transition, Dark matter and neutrino cosmology, Non-equilibrium quantum field theory