Exclusive and semiexclusive production of $\mu^+ \mu^-$ pairs with $\Delta$ isobars and other resonances in the final state and the size of absorption effects

TL;DR

This paper investigates exclusive and semi-exclusive muon pair production in proton-proton collisions, including resonance contributions and absorption effects, revealing that these processes significantly impact cross section measurements and interpretations.

Contribution

It introduces calculations of resonance-involved processes in muon pair production, highlighting their influence on cross sections and the importance of absorption effects in theoretical models.

Findings

Calculated total cross section exceeds experimental measurements.

Absorption effects increase cross section by about 10%.

Resonance processes can significantly affect muon pair production interpretations.

Abstract

We include $p p \to p \Delta^{+} \mu^{+} \mu^{-}$ and $p p \to \Delta^{+} \Delta^{+} \mu^{+} \mu^{-}$ processes in addition to the standard $p p \to p p \mu^{+} \mu^{-}$ process both in equivalent-photon approximation (EPA) and in exact $2 \to 4$ calculations. For comparison we calculate also the continuum proton dissociation in a recently developed $k_{t}$-factorization approach to $\gamma \gamma$-involved processes with parametrizations of $F_{2}$ structure function known from the literature. The calculated cross section including all the processes is considerably larger than the one measured recently by the ATLAS collaboration. We calculate absorption effects for $p p \to p p \mu^{+} \mu^{-}$ process in the momentum space. The final cross section with absorption effects is by 10\% larger than the one measured by the ATLAS collaboration which is difficult to explain. Several differential distributions with the ATLAS experimental cuts are presented. It is shown that the processes with electromagnetic $p \to \Delta(1232)$ and $p \to N(1440)$ transitions, that have similar characteristics as the $p p \to p p \mu^+ \mu^-$ process, increase the cross section for $\mu^+ \mu^-$ production and thus can affect its theoretical interpretation when the leading baryons are not detected as is the case for the CMS and ATLAS measurements. The mechanism of dissociation into hadronic continuum is not under full control as the corresponding absorption effects are not fully understood. We present first predictions for future ATLAS experiment with the ALFA sub-detectors and discuss observables relevant for this measurement.