High Energy Physics Journal Club

Report on Collider signals of a composite Higgs in the Standard Model with four generations

by Biplob Bhattacharjee

Friday, January 29, 2010 from to (Asia/Kolkata)
at Colaba Campus ( A-304 )
Description
Authors: Shaouly Bar-Shalom, Gad Eilam, Amarjit Soni

Recent fits of electroweak precision data to the Standard Model (SM) with a 4th sequential family (SM4) point to a possible "three-prong composite solution": (1) the Higgs mass is at the TeV-scale, (2) the masses of the 4th family quarks t',b' are of O(500) GeV and (3) the mixing angle between the 4th and 3rd generation quarks is of the order of the Cabibbo angle, \theta_{34} ~ O(0.1). Such a manifestation of the SM4 is of particular interest as it may suggest that the Higgs is a composite state, predominantly of the 4th generation heavy quarks. Motivated by the above, we show that the three-prong composite solution to the SM4 can have interesting new implications for Higgs phenomenology. For example, the Higgs can decay to a single heavy 4th generation quark via the 3-body decays (through an off-shell t' or b') H -> t'(bar) t'* -> t'(bar) b W+ and H -> b'(bar) b'* -> b'(bar) t W-. These flavor diagonal decays can be dramatically enhanced at the LHC (by several orders of magnitudes) due to the large width effects of the resonating heavy Higgs in the processes gg -> H -> t'(bar) t'* -> t'(bar) b W+ and gg -> H -> b'(bar) b'* -> b'(bar) t W-, thus yielding a viable signal above the corresponding continuum QCD production rates. In addition, the Higgs can decay to a single t' and b' in the loop-generated flavor changing (FC) channels H -> b' b(bar), t' t(bar). These FC decays are essentially "GIM-free" and can, therefore, have branching ratios as large as 10^{-4} - 10^{-3}. 
Participants Debasish Banerjee; Raju Bathija; Rajeev Bhalerao; Biplob Bhattacharjee; Saumen Datta; Amol Dighe; Rajiv Gavai; Sourendu Gupta; Vinod Joshi; Sridhar K.; Padmanath M.; Jyotirmoy Maiti; Nilmani Mathur; Subroto Pal; Sreerup Raychaudhuri; Anurag Tripathy
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