Null test BSM searches with rare charm baryon decays

TL;DR

This paper explores rare charm baryon decays as null tests for new physics, highlighting their potential to detect BSM effects with high sensitivity through angular observables.

Contribution

It introduces novel null test observables in rare charm baryon decays that can probe BSM physics with enhanced sensitivity, especially in electromagnetic and four-fermion couplings.

Findings

Sensitivity to BSM couplings as small as ~0.01

Angular observables can disentangle new physics effects

Resonance contributions enhance new physics signals

Abstract

Rare $\vert \Delta c \vert=\vert \Delta u \vert=1$ processes uniquely probe flavor in the Standard Model and beyond from the up-type quark sector. Opportunities to search for BSM physics in charm arise from the severe GIM suppression which kills SM contributions to leptonic axial-vector contributions and suppresses CP violation. Semileptonic decays of charmed hadrons offer a variety of clean null test observables, featuring new physics effects which are even enhanced by resonance contributions. In particular, angular observables in three- and self-analyzing four-body baryon decays, such as $\Lambda_c\to p \ell^+\ell^-$ and $\Xi_c^+\to\Sigma^+(\to p\pi^0)\ell^+\ell^-$, $\Xi_c^0\to\Lambda^0\,(\to p \pi^-)\ell^+\ell^-$ and $\Omega_c^0\to\Xi^0\,(\to \Lambda^{0} \pi^0)\ell^+\ell^-$ disentangle possible new physics effects in electromagnetic dipole couplings $C_7^{(\prime)}$ and (axial-)vector 4-fermion ones $C^{(\prime)}_{9\,(10)}$. There is sensitivity to BSM couplings as small as $\sim 0.01$.