顾嘉荫 青年研究员 2014年加州大学戴维斯分校博士 Email: jiayin_gu@fudan.edu.cn 主要经历: 2008.10-2009.9杜伦大学(University of Durham)硕士 2009.9-2014.6 加州大学戴维斯分校(UC Davis)博士 2014.8-2018.4 中国科学院高能物理研究所博士后 2016.3-2018.2 德国电子同步加速器研究中心(DESY)访问博士后 2018.9-2021.8 德国美因茨约翰内斯古滕贝格大学(Mainz)博士后 2021.9-至今 beat365手机官方网站青年研究员 教学与研究领域: Jiayin Gu Associate Professor Ph.D(2014), University of California, Davis Selected Publications: 1)J. Gu, L.-T. Wang, and C. Zhang, An unambiguous test ofpositivity at lepton colliders, [arXiv:2011.03055]. 2)J. Gu and L.-T. Wang, Sum Rules in the Standard Model Effective Field Theory from Helicity Amplitudes, JHEP 03 (2021) 149, [arXiv:2008.07551].
3)J. De Blas, G. Durieux, C. Grojean, J. Gu, and A. Paul, On the future of Higgs, electroweak and diboson measurements at lepton colliders, JHEP 12 (2019) 117, [arXiv:1907.04311].
4)G. Durieux, J. Gu, E. Vryonidou, and C. Zhang, Probing top-quark couplings indirectly at Higgs factories, Chin. Phys. C42 (2018), no. 12 123107, [arXiv:1809.03520]. 5)S. Di Vita, G. Durieux, C. Grojean, J. Gu, Z. Liu, G. Panico, M. Riembau, and T. Vantalon, A global view on the Higgs self-coupling at lepton colliders, JHEP 02 (2018) 178, [arXiv:1711.03978].
6)G. Durieux, C. Grojean, J. Gu, and K. Wang, The leptonic future of the Higgs, JHEP 09 (2017) 014, [arXiv:1704.02333].
7)N. Craig, J. Gu, Z. Liu, and K. Wang, Beyond Higgs Couplings: Probing the Higgs with Angular Observables at Future e+e− Colliders, JHEP 03 (2016) 050, [arXiv:1512.06877].
8)Y. Bai, H.-C. Cheng, J. Gallicchio, and J. Gu, Stop the Top Background of the Stop Search, JHEP 07 (2012) 110, [arXiv:1203.4813].
2004.10-2008.6杜伦大学(University of Durham)硕士 (本硕连读)
研究领域:粒子物理理论与唯象学。主要研究方向包括: 1.标准模型有效场论的理论研究和唯象学分析。2. 对于未来对撞机上希格斯粒子,电弱玻色子以及顶夸克精确测量的物理前景分析。3.对超出标准模型的新物理的探索。4.振幅方法和色散关系在有效场论中的应用。
My main research area is in high energy theory and phenomenology. My research interests include 1) formal developments and collider phenomenology of the Standard Model Effective Field Theory, 2) precision Higgs, electroweak and top physics at future colliders, 3) searches of new physics beyond the Standard Model, and 4) applications of scattering amplitudes and dispersion relations in effective field theories.