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The discovery of a Higgs boson at CERN’s Large Hadron Collider (LHC) by the ATLAS and CMS collaborations testifies to the success of the Standard Model (SM) of particle physics. However, the Standard Model does not address fundamental questions such as: Why is gravity so much weaker than electroweak force? What is the nature of Dark Matter? Why is there an imbalance between matter and anti-matter in the universe? Experimental observations have indicated that the Standard Model is likely to be an effective theory at low energy and new physics phenomena may appear at the TeV-scale accessible by the LHC.
We live in an exciting time for particle physics. The excellent performance of the current LHC as well as the High Luminosity LHC (HL-LHC) upgrade, allows us to confront those fundamental questions with a large and ever-increasing data set. The long-awaited discovery of Beyond the Standard Model (BSM) physics may well be right around the corner. Currently, my research is focused on discovering new physics phenomena at the LHC. Specifically, my research program will probe BSM physics by precision measurement and testing of the Standard Model in the Higgs sector and by direct searches for signals of a broad spectrum of well-motivated BSM models. To further exploit the physics potential of the LHC, I am also contributing to the upgrade of the ATLAS detector for the upcoming HL-LHC.
I am a member of the Berkeley LBNL ATLAS group, which consists of two other UC faculty members, Professors Gray and Shapiro, over a dozen staff scientists at the Lawrence Berkeley National Laboratory, many postdoctoral researchers, UC graduate students, undergraduate students and visitors.
The discovery of a Higgs boson at CERN’s Large Hadron Collider (LHC) by the ATLAS and CMS collaborations testifies to the success of the Standard Model (SM) of particle physics. However, the Standard Model does not address fundamental questions such as: Why is gravity so much weaker than electroweak force? What is the nature of Dark Matter? Why is there an imbalance between matter and anti-matter in the universe? Experimental observations have indicated that the Standard Model is likely to be an effective theory at low energy and new physics phenomena may appear at the TeV-scale accessible by the LHC.
We live in an exciting time for particle physics. The excellent performance of the current LHC as well as the High Luminosity LHC (HL-LHC) upgrade, allows us to confront those fundamental questions with a large and ever-increasing data set. The long-awaited discovery of Beyond the Standard Model (BSM) physics may well be right around the corner. Currently, my research is focused on discovering new physics phenomena at the LHC. Specifically, my research program will probe BSM physics by precision measurement and testing of the Standard Model in the Higgs sector and by direct searches for signals of a broad spectrum of well-motivated BSM models. To further exploit the physics potential of the LHC, I am also contributing to the upgrade of the ATLAS detector for the upcoming HL-LHC.
I am a member of the Berkeley LBNL ATLAS group, which consists of two other UC faculty members, Professors Gray and Shapiro, over a dozen staff scientists at the Lawrence Berkeley National Laboratory, many postdoctoral researchers, UC graduate students, undergraduate students and visitors.
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EUROPEAN PHYSICAL JOURNAL Cno. 7 (2023): 1-6
arxiv(2023)
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Bulletin of the American Physical Society (2021)
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