Exotic-interaction searches on small scales via near-threshold enhancement

TL;DR

This paper introduces a novel near-threshold enhancement method to improve laboratory searches for exotic fermion interactions mediated by new bosons, significantly extending the detectable force range and sensitivity.

Contribution

It proposes leveraging near-threshold enhancement to overcome force range limitations in detecting exotic interactions, enabling larger experimental setups and improved sensitivity.

Findings

Potential to improve bounds on coupling constants by 10 orders of magnitude at 800 μeV.

Method extends the search for exotic interactions to higher mass ranges.

Enhances the study of new physics beyond the Standard Model.

Abstract

Exotic interactions between fermions mediated by new bosons beyond the Standard Model may hold the key to several fundamental conundrums on the frontier of physics.However, laboratory searching for exotic interactions on small length scales is fundamentally held back by the short force range.Here we propose that the force range of exotic interactions tends to infinity when the oscillation frequency of exotic interactions approaches the mass of the new bosons, i.e., the new bosons become nearly on-shell. This is named as the near-threshold enhancement. Through the near-threshold enhancement, even fermions at distances larger than the original force range can make considerable contributions to exotic interactions. Therefore, the size of the experimental apparatus can break the limitation of the force range, and thus both the signal of exotic interactions and the sensitivity of sensors can be greatly enhanced. We also propose a method to search for the exotic interactions in the mass range between 80 $\mu$eV and 800 $\mu$eV taking advantage of the near-threshold enhancement. For the coupling $g_{\rm A}^{\rm e}g_{\rm A}^{\rm e}$, we expect an improvement on its upper bounds of 10 orders of magnitude at 800 $\mu$eV. This method can be further extended to enhance the search for other types of exotic interactions and boost the study of new physics beyond the Standard Model.