His primary areas of study are Particle physics, Large Hadron Collider, Nuclear physics, Higgs boson and Physics beyond the Standard Model. His research in Standard Model, Neutrino, Collider, Electroweak interaction and Gauge boson are components of Particle physics. The Neutrino study combines topics in areas such as Lepton number and Lepton.
His work deals with themes such as Invariant mass, Hadron, Supersymmetry and Observable, which intersect with Large Hadron Collider. The study incorporates disciplines such as Production and Muon collider in addition to Nuclear physics. His Higgs boson study combines topics from a wide range of disciplines, such as Boson and Technicolor.
His main research concerns Particle physics, Higgs boson, Large Hadron Collider, Nuclear physics and Standard Model. His study in Physics beyond the Standard Model, Electroweak interaction, Supersymmetry, Collider and Boson is done as part of Particle physics. His studies in Higgs boson integrate themes in fields like Elementary particle and Gauge boson.
His work on Luminosity is typically connected to Coupling as part of general Large Hadron Collider study, connecting several disciplines of science. In his research, Muon is intimately related to Muon collider, which falls under the overarching field of Nuclear physics. His biological study deals with issues like Gluon, which deal with fields such as Annihilation.
Tao Han mainly investigates Particle physics, Higgs boson, Physics beyond the Standard Model, Large Hadron Collider and Standard Model. His research investigates the link between Particle physics and topics such as Lepton that cross with problems in Muon. His Higgs boson research is multidisciplinary, incorporating elements of Fermion, Yukawa potential, Nuclear physics and Observable.
His Physics beyond the Standard Model research integrates issues from Minimal Supersymmetric Standard Model, Top quark, Higgs sector, Energy and Pair production. His studies deal with areas such as Center of mass, Supersymmetry, Effective field theory and Quark as well as Large Hadron Collider. His Standard Model research is multidisciplinary, relying on both Higgs field, Hadron, Type and Loop.
The scientist’s investigation covers issues in Particle physics, Higgs boson, Large Hadron Collider, Physics beyond the Standard Model and Collider. His work is connected to Standard Model, Dark matter, Neutrino, Electroweak interaction and Vector boson, as a part of Particle physics. His Higgs boson research includes themes of Luminosity and Lepton.
His study looks at the relationship between Large Hadron Collider and fields such as Parton, as well as how they intersect with chemical problems. His Physics beyond the Standard Model study incorporates themes from Supersymmetry, Effective field theory and Observable. His Collider study improves the overall literature in Nuclear physics.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Handbook of LHC Higgs cross sections: 4. Deciphering the nature of the Higgs sector
D. de Florian;C. Grojean;F. Maltoni;C. Mariotti.
CERN Yellow Reports: Monographs; (2016) (2016)
The snowmass Points and slopes: benchmarks for SUSY searches
B. C. Allanach;M. Battaglia;G. A. Blair;M. Carena.
European Physical Journal C (2002)
On Kaluza-Klein states from large extra dimensions
Tao Han;Joseph D. Lykken;Ren-Jie Zhang.
Physical Review D (1999)
Some new aspects of supersymmetry R -parity violating interactions
Vernon D. Barger;G.F. Giudice;Tao Han.
Physical Review D (1989)
Phenomenology of the little Higgs model
Tao Han;Heather E. Logan;Bob McElrath;Lian-Tao Wang.
Physical Review D (2003)
The Search for Heavy Majorana Neutrinos
Anupama Atre;Anupama Atre;Tao Han;Tao Han;Tao Han;Silvia Pascoli;Bin Zhang.
Journal of High Energy Physics (2009)
Simplified Models for LHC New Physics Searches
Daniele Alves;Nima Arkani-Hamed;Sanjay Arora;Yang Bai.
Journal of Physics G (2012)
A Large Hadron Electron Collider at CERN: Report on the Physics and Design Concepts for Machine and Detector
J. L. Abelleira Fernandez;C. Adolphsen;A. N. Akay;H. Aksakal.
arXiv: Accelerator Physics (2012)
First look at the physics case of TLEP
M. Bicer;H. Duran Yildiz;I. Yildiz;G. Coignet.
Journal of High Energy Physics (2014)
TESLA Technical Design Report Part III: Physics at an e+e- Linear Collider
R. D. Heuer;D. J. Miller;F. Richard;P. M. Zerwas.
arXiv: High Energy Physics - Phenomenology (2001)
If you think any of the details on this page are incorrect, let us know.
We appreciate your kind effort to assist us to improve this page, it would be helpful providing us with as much detail as possible in the text box below: