Tagging more quark jet flavours at FCC-ee at 91 GeV with a transformer-based neural network

Abstract

Jet flavour tagging is crucial in experimental high-energy physics. A tagging algorithm, DeepJetTransformer, is presented, which exploits a transformer-based neural network that is substantially faster to train than state-of-the-art graph neural networks. The DeepJetTransformer algorithm uses information from particle flow-style objects and secondary vertex reconstruction for b- and c-jet identification, supplemented by additional information that is not always included in tagging algorithms at the LHC, such as reconstructed KS0 and 0 and K/π discrimination. The model is trained as a multiclassifier to identify all quark flavours separately and performs excellently in identifying b- and c-jets. An s-tagging efficiency of 40\% can be achieved with a 10\% ud-jet background efficiency. The performance improvement achieved by including KS0 and 0 reconstruction and K/π discrimination is presented. The algorithm is applied on exclusive Z qq samples to examine the physics potential and is shown to isolate Z ss events. Assuming all non-Z qq backgrounds can be efficiently rejected, a 5σ discovery significance for Z ss can be achieved with an integrated luminosity of 60~nb-1 of e+e- collisions at s=91.2~GeV, corresponding to less than a second of the FCC-ee run plan at the Z boson resonance.