Probing the electromagnetic properties of the neutrinos at future lepton colliders

TL;DR

This paper investigates the potential of future lepton colliders to probe non-standard neutrino electromagnetic interactions, providing projected sensitivity limits that surpass current bounds by many orders of magnitude.

Contribution

It introduces a detailed Monte Carlo simulation framework to evaluate collider sensitivities to neutrino-photon couplings via specific processes at future colliders.

Findings

Projected sensitivities significantly improve current bounds.

Muon colliders offer complementary probing capabilities.

Limits are up to thirteen orders of magnitude stronger than previous constraints.

Abstract

In this study, we explore the non-standard $\nu\bar{\nu}\gamma \gamma$ couplings parametrized by dimension-seven operators via $e^{+}e^{-} \to \nu\bar{\nu}\gamma$ process at the FCC-ee/CEPC and $\mu^{+}\mu^{-}\to\nu\bar{\nu}\gamma$ process at the Muon Colliders. For the detailed Monte Carlo simulation, all signal and relevant background events are produced within the framework of Madgraph where non-standard $\nu\bar{\nu}\gamma \gamma$ couplings are implemented. After passing through Pythia for parton showering and hadronization, detector effects are included via tuned corresponding detector cards for each collider in Delphes. Projected sensitivities on $\nu\bar{\nu}\gamma \gamma$ couplings are obtained at a 5$\sigma$ confidence level without and with $5\%$ systematic uncertainties for the FCC-ee/CEPC and the Muon Colliders, showcasing the complementarity between lepton colliders. Our best limit on the anomalous $\nu\bar{\nu}\gamma \gamma$ couplings even with 5\% systematic uncertainties for muon collider with $\sqrt{s}=10$ TeV and $L_{int}=3$ ab$^{-1}$ are found to be thirteen orders of magnitude stronger than the upper bound obtained from rare decay $Z\to\gamma\gamma\nu\bar{\nu}$ analysis using LEP data.