Expanding the Reach of Heavy Neutrino Searches at the LHC

Abstract

The observation of neutrino oscillations establishes that neutrinos () have non-zero mass and provides one of the more compelling arguments for physics beyond the standard model (SM) of particle physics. We present a feasibility study to search for hypothetical Majorana neutrinos (N) with TeV scale masses, predicted by extensions of the SM to explain the small but non-zero mass, using vector boson fusion (VBF) processes at the 13 TeV LHC. In the context of the minimal Type-I seesaw mechanism (mTISM), the VBF N production cross-section surpasses that of the Drell-Yan process at approximately mN = 1.4 TeV. We consider μ Nμ and τ Nτ production through VBF processes (e.g. qq' τ Nτqq'), with subsequent Nμ and Nτ decays to μ jj and τ jj, as benchmark cases to show the effectiveness of the VBF topology for N seaches at the 13 TeV LHC. The requirement of a dilepton pair combined with four jets, two of which are identified as VBF jets with large separation in pseudorapidity and a TeV scale dijet mass, is effective at reducing the SM background. This criteria may provide expected exclusion bounds, at 95\% confidence level, of mN < 1.7 (2.4) TeV, assuming 100 (1000) fb-1 of 13 TeV data from the LHC and mixing |V N|2 = 1. The use of the VBF topology to search for mN increases the discovery reach at the LHC, with expected significances greater than 5σ (3σ) for N masses up to 1.7 (2.05) TeV using 1000 fb-1 of 13 TeV data from the LHC.