Parton distribution function uncertainties in theoretical predictions for far-forward tau neutrinos at the Large Hadron Collider

TL;DR

This paper assesses the uncertainties in predicting tau neutrino fluxes at the LHC due to parton distribution functions, highlighting significant variations and the potential for future experimental constraints.

Contribution

It provides a detailed evaluation of PDF uncertainties in NLO QCD calculations of tau neutrino fluxes in the far-forward region at the LHC, emphasizing their impact on theoretical predictions.

Findings

PDF uncertainties contribute ±20-30% to tau neutrino flux predictions.

Scale uncertainties can cause predictions to vary by -70% to +90%.

Predicted neutrino energy distributions differ by a factor of 2-4 across PDF sets.

Abstract

New experiments to measure neutrinos in the far-forward region at the Large Hadron Collider (LHC) are under design or already in preparation. Two of them, FASER$\nu$ and SND@LHC, are expected to be active during Run 3 and have the potential to detect neutrinos that come from high-energy collisions in one of the LHC interaction points, extracted along the direction tangent to the beam line. Tau neutrinos and antineutrinos come predominantly from $D_s^\pm$ production in $pp$ collisions, followed by the leptonic decay of these mesons. Neutrino pseudorapidities in the range of $\eta>6.9$ and $\eta>8.9$ are relevant to these future experiments. At such pseudorapidities at high energies, theoretical predictions for the flux of tau neutrinos rely on parton distribution functions (PDFs) in a combination of very small and large parton$-x$ values. We evaluate PDF uncertainties in a next-to-leading order (NLO) QCD calculation of the flux of $\nu_\tau$ + $\bar{\nu}_\tau$ produced by $D_s^\pm$ decay in the far forward region at the LHC. The theoretical uncertainty associated with the 40 PDF sets of the PROSA19 group amounts to $\pm (20-30)$\% for the ($\nu_\tau$ + $\bar{\nu}_\tau$) number of charged-current (CC) events. Scale uncertainties are much larger, resulting in a range of CC event predictions from $\sim 70\%$ lower to $\sim 90\%$ higher than the central prediction. A comparison of the predictions with those obtained using as input the central PDFs from the 3-flavour NLO PDF sets of the CT14, ABMP16 and NNPDF3.1 collaborations show that far-forward neutrino energy distributions vary by as much as a factor of $\sim 2-4$ relative to the PROSA19 predictions at TeV neutrino energies. The Forward Physics Facility in the high luminosity LHC era will provide data capable of constraining NLO QCD evaluations with these PDF sets.