Abstract
We consider the possibility of probing left-right symmetric model (LRSM) via cosmic microwave background (CMB). We adopt the minimal LRSM with Higgs doublets, also known as the doublet left-right model (DLRM), where all fermions including the neutrinos acquire masses only via their couplings to the Higgs bidoublet. Due to the Dirac nature of light neutrinos, there exist additional relativistic degrees of freedom which can thermalise in the early universe by virtue of their gauge interactions corresponding to the right sector. We constrain the model from Planck 2018 bound on the effective relativistic degrees of freedom and also estimate the prospects for planned CMB Stage IV experiments to constrain the model further. We find that $W_R$ boson mass below 4.06 TeV can be ruled out from Planck 2018 bound at $2\sigma$ CL in the exact left-right symmetric limit which is equally competitive as the LHC bounds from dijet resonance searches. On the other hand Planck 2018 bound at $1\sigma$ CL can rule out a much larger parameter space out of reach of present direct search experiments, even in the presence of additional relativistic degrees of freedom around the TeV corner. We also study the consequence of these constraints on dark matter in DLRM by considering a right handed real fermion quintuplet to be the dominant dark matter component in the universe.
Highlights
Left-right symmetric models (LRSMs) [1,2,3,4,5,6,7,8,9,10,11,12] have been one of the most popular beyond the standard model (BSM) frameworks studied in the literature
The Dirac nature of light neutrinos in the doublet leftright model (DLRM) gives rise to additional relativistic degrees of freedom which can be thermalized in the early Universe due to their gauge interactions mediated by right sector gauge bosons
We show the impact of these constraints on dark matter (DM) parameter space in the DLRM by considering a right-handed fermion quintuplet to be the dominant component of DM which can thermalize by virtue of its interactions with the SM mediated by right sector gauge bosons
Summary
Left-right symmetric models (LRSMs) [1,2,3,4,5,6,7,8,9,10,11,12] have been one of the most popular beyond the standard model (BSM) frameworks studied in the literature. In the doublet left-right model (DLRM), in its minimal version, there is no such seesaw mechanism, as all fermions including neutrinos acquire Dirac masses by virtue of their couplings to the bidoublet scalar. The Dirac nature of light neutrinos in the DLRM gives rise to additional relativistic degrees of freedom which can be thermalized in the early Universe due to their gauge interactions mediated by right sector gauge bosons. We comment on the more stringent Planck 2018 1σ bound which can be satisfied if more light fields below the scale of left-right symmetry breaking in addition to the SM plus three right-handed neutrinos exist.
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