Probing Neutral Triple Gauge Couplings via ZZ Production at e+e- Colliders with Machine Learning

Abstract

Neutral triple gauge couplings (nTGCs) first arise from the dimension-8 operators of the Standard Model Effective Field Theory (SMEFT), rather than the dimension-4 SM Lagrangian and dimension-6 SMEFT operators, opening up a unique window for probing new physics at the dimension-8 level. In this work, we formulate the nTGC form factors of ZZV* (V\!\!=\!Z,γ) that are compatible with the spontaneous breaking of the SU(2)(1) electroweak gauge symmetry and consistently match the dimension-8 nTGC operators in the broken phase. We study the sensitivities for probing both the ZZV* form factors and the corresponding new physics scales through ZZ production (with visible/invisible fermionic Z decays) at high energy e+e- colliders including CEPC, FCC-ee, ILC and CLIC. In particular, we identify the dimension-8 operator that contributes to the pure triple Z boson coupling ZZZ* alone, but not the mixed ZZγ* coupling. We further study the correlations between probes of the ZZZ* and ZZγ* couplings. Using machine learning, we show that angular distributions of the final-state fermions can play key roles in suppressing the SM backgrounds. The sensitivities can be further improved by using polarized e beams. We demonstrate that machine learning is advantageous for handling the 4-body final states from ZZ decays and improves significantly the sensitivity reaches of probes of nTGCs in e+e- collisions. We find that nTGC new physics scales can be probed up to the multi-TeV scale at the proposed e+e- colliders.