We present a study of the central exclusive production (CEP) of meson pairs 1 , M M , at sufficiently high invariant mass that a perturbative QCD formalism is applicable. Within this framework, M M production proceeds via the gg → M M hard scattering sub-process, which can be calculated within the hard exclusive formalism. We present explicit calculations for the gg → M M helicity amplitudes for different meson states and, using these, show results for meson pair CEP in the perturbative regime. a KRYSTHAL collaboration b speaker
We present a range of physics results for central exclusive production processes at the LHC, using the new SuperChic 2 Monte Carlo event generator. This includes significant theoretical improvements and updates, most importantly a fully differential treatment of the soft survival factor, as well as a greater number of generated processes. We provide an overview of the latest theoretical framework, and consider in detail a selection of final states, namely exclusive 2 and 3 jets, photoproduced vector mesons, two-photon initiated muon and W boson pairs and heavy χ c,b quarkonia.
Central exclusive production (CEP) processes in high-energy proton -(anti)proton collisions offer a very promising framework within which to study both novel aspects of QCD and new physics signals. Among the many interesting processes that can be studied in this way, those involving the production of heavy (c, b) quarkonia and γγ states have sufficiently well understood theoretical properties and sufficiently large cross sections that they can serve as 'standard candle' processes with which we can benchmark predictions for new physics CEP at the CERN Large Hadron Collider. Motivated by the broad agreement with theoretical predictions of recent CEP measurements at the Fermilab Tevatron, we perform a detailed quantitative study of heavy quarkonia (χ and η) and γγ production at the Tevatron, RHIC and LHC, paying particular attention to the various uncertainties in the calculations. Our results confirm the rich phenomenology that these production processes offer at present and future high-energy colliders.
Motivated by the recent experimental observation of exclusive χ c events at the Tevatron, we revisit earlier studies of central exclusive scalar χ c0 meson production, before generalising the existing formalism to include χ c1 and χ c2 mesons. Although χ c0 production was previously assumed to be dominant, we find that the χ c1 and χ c2 rates for the experimentally considered χ c → J/ψγ → µ + µ − γ decay process are in fact comparable to the χ c0 rate. We have developed a new Monte Carlo event generator, SuperCHIC, which models the central exclusive production of the three χ c states via this decay chain, and have explored possible ways of distinguishing them, given that their mass differences are not resolvable within the current experimental set-up. Although we find that the severity of current experimental cuts appears to preclude this, the acceptance does not change crucially between the three states and so our conclusions regarding the overall rates remain unchanged. This therefore raises the interesting possibility that exclusive χ c1 and χ c2 production has already been observed at the Tevatron.2 In the χc case the agreement becomes especially striking after taking into account the revised value of the total χc0 width which has been reduced by a factor 1.4 [37] as compared to the value in the Review of Particle Properties (2002) used in [5].3 CHIC is a publicly available Monte Carlo implementation of the χc0 analysis of Ref. [5]. 4 This applies not only to χc(1P ) states, but also to possible higher excitations χc(nP ). 5 S enh is largely independent of the χ spin assignment. Note also that the relative number of events where the forward protons dissociate is larger for χc1 and χc2 than for χc0.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.