Spin Correlations in Dark Photon Searches

TL;DR

This paper analyzes spin correlations in dark photon production and decay, providing analytic tools to estimate their effects, which are negligible for current experiments but significant for future searches like SHiP.

Contribution

The authors derive analytic results for spin correlations in dark photon processes and quantify their impact, highlighting when these effects can be neglected or must be considered.

Findings

Spin correlations are less than approximately 9.6% in typical scenarios.

Effects are negligible for current FASER analyses.

Spin correlations can significantly reduce event rates at future SHiP searches.

Abstract

We investigate the spin correlations between production and decay in the process where dark photons $A'$ are produced in pseudoscalar meson decays, for example, $\pi^0, \eta \to \gamma A'$, and then decay to fermion pairs, $A' \to f \bar{f}$. This process is the focus of many experimental searches, but spin correlations are typically ignored. We derive analytic results that allow us to quickly scan parameter space and quantify the error made in neglecting spin correlations. In particular, we define a discrepancy parameter and find that this parameter is always less than $\frac{1}{6\sqrt{3}} \approx 9.6\%$, which provides a rough measure of the size of spin correlation effects. However, these effects may be enhanced or suppressed by cuts in realistic experimental analyses, and so we also consider two representative examples, including current FASER analyses and possible future searches at SHiP. We find that the effects of spin correlations are negligible for existing FASER analyses, but can significantly reduce event rates at upcoming SHiP searches.