Ad Lucem: QED parton distribution functions in the MMHT framework

Harland–Lang, Lucian; Martin, A.; Nathvani, R.; Thorne, R. S.

doi:10.1140/epjc/s10052-019-7296-0

Cited by 73 publications

(102 citation statements)

References 59 publications

(106 reference statements)

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“…In more detail, the structure function receives contributions from: elastic photon emission, for which we use the A1 collaboration [43] fit to the elastic proton form factors; CLAS data on inelastic structure functions in the resonance W 2 < 3.5 GeV 2 region, primarily concentrated at lower Q 2 due to the W 2 kinematic requirement; the HERMES fit [44] to the inelastic low Q 2 < 1 GeV 2 structure functions in the continuum W 2 > 3.5 GeV 2 region; inelastic high Q 2 > 1 GeV 2 structure functions for which the pQCD prediction in combination with PDFs determined from a global fit provide the strongest constraint (we take the ZM-VFNS at NNLO in QCD predictions for the structure functions as implemented in APFEL [45], with the MMHT2015qed_nnlo PDFs throughout, though in the MC the PDF can be set by the user). The inputs we take are as discussed in the MMHT15 photon PDF determination [46], which itself is closely based on that described in [1,2] for the LUXqed set. However, we note that our calculation makes no explicit reference to the partonic content of the proton itself, and as discussed in detail in [3] provides by construction a more precise prediction than the result within collinear factorization that uses such a photon PDF.…”

Section: Structure Function Calculationmentioning

confidence: 99%

“…The survival factor is modelled in a rather similar way to the MC implementation. To compare more directly, we have in fact modified the photon PDF to more closely match the MMHT15 photon [46], while we also show the effect of varying the factorization/renormalization scale by a factor of 2 around the central value of μ = M ll to give an estimate of the uncertainty in the prediction in the inclusive case. We can see that broadly the analytic results are in good agreement with the more precise MC implementation, with the approximate treatment of LO collinear factorization framework and the rapidity veto giving a fair description of the overall trends.…”

Section: Impact Of Rapidity Vetomentioning

confidence: 99%

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A new approach to modelling elastic and inelastic photon-initiated production at the LHC: SuperChic 4

Harland–Lang¹,

Taševský

Хозе

et al. 2020

Eur. Phys. J. C

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We present the results of the new Monte Carlo implementation of photon-initiated production in proton–proton collisions, considering as a first example the case of lepton pair production. This is based on the structure function calculation of the underlying process, and focusses on a complete account of the various contributing channels, including the case where a rapidity gap veto is imposed. We provide a careful treatment of the contributions where either (single dissociation), both (double dissociation) or neither (elastic) proton interacts inelastically and dissociates, and interface our results to for showering and hadronization. The particle decay distribution from dissociation system, as well the survival probability for no additional proton–proton interactions, are both fully accounted for; these are essential for comparing to data where a rapidity gap veto is applied. We present detailed results for the impact of the veto requirement on the differential cross section, compare to and find good agreement with ATLAS 7 TeV data on semi-exclusive production, and provide a new precise evaluation of the background from semi-exclusive lepton pair production to SUSY particle production in compressed mass scenarios, which is found to be low.

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Section: Structure Function Calculationmentioning

confidence: 99%

Section: Impact Of Rapidity Vetomentioning

confidence: 99%

A new approach to modelling elastic and inelastic photon-initiated production at the LHC: SuperChic 4

Harland–Lang¹,

Taševský

Хозе

et al. 2020

Eur. Phys. J. C

Self Cite

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show abstract

“…Finally, hard processes initiated by vector bosons have been considered for a long time [80,81]. PDF sets with QED corrections have been available for some time [82][83][84][85], and recent progress was made towards PDFs with complete electroweak corrections [86][87][88]. The current shower implementation only allows for the emission of vector bosons from the initial state.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Collinear electroweak radiation in antenna parton showers

Kleiss

Verheyen

2020

Eur. Phys. J. C

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We present a first implementation of collinear electroweak radiation in the Vincia parton shower. Due to the chiral nature of the electroweak theory, explicit spin dependence in the shower algorithm is required. We thus use the spinor-helicity formalism to compute helicity-dependent branching kernels, taking special care to deal with the gauge relics that may appear in computation that involve longitudinal polarizations of the massive electroweak vector bosons. These kernels are used to construct a shower algorithm that includes all possible collinear final-state electroweak branchings, including those induced by the Yang–Mills triple vector boson coupling and all Higgs couplings, as well as vector boson emissions from the initial state. We incorporate a treatment of features particular to the electroweak theory, such as the effects of bosonic interference and recoiler effects, as well as a preliminary description of the overlap between electroweak branchings and resonance decays. Some qualifying results on electroweak branching spectra at high energies, as well as effects on LHC physics are presented. Possible future improvements are discussed, including treatment of soft and spin effects, as well as issues unique to the electroweak sector.

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“…Second, in order to evaluate flavour-scheme uncertainties, both a 4FS and a 5FS version of the same PDF fit have to be available. Therefore, the only three possible options at the moment are: NNPDF3.0 [41,42], NNPDF3.1 [43,44] and MMHT2014/MMHT2015 [45,46]. All these three sets are accurate up to NNLO in QCD and NLO in QED accuracy and include a photon density based on the LUXqed parameterisation [47,48].…”

Section: Input Parametersmentioning

confidence: 99%

NLO QCD+EW predictions for tHj and tZj production at the LHC

Pagani¹,

Tsinikos

Vryonidou

2020

J. High Energ. Phys.

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In this work we calculate the cross sections for the hadroproduction of a single top quark or antiquark in association with a Higgs (tHj) or Z boson (tZj) at NLO QCD+EW accuracy. In the case of tZj production we consider both the case of the Z boson undecayed and the complete final state t + − j, including off-shell and non-resonant effects. We perform our calculation in the five-flavour-scheme (5FS), without selecting any specific production channel (s-, tor tW associated). Moreover, we provide a more realistic estimate of the theory uncertainty by carefully including the differences between the fourflavour-scheme (4FS) and 5FS predictions. The difficulties underlying this procedure in the presence of EW corrections are discussed in detail. We find that NLO EW corrections are in general within the NLO QCD theory uncertainties only if the flavour scheme uncertainty (4FS vs. 5FS) is taken into account. For the case of t + − j production we also investigate differences between NLO QCD+EW predictions and NLO QCD predictions matched with a parton shower simulation including multiple photon emissions.

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Ad Lucem: QED parton distribution functions in the MMHT framework

Cited by 73 publications

References 59 publications

A new approach to modelling elastic and inelastic photon-initiated production at the LHC: SuperChic 4

A new approach to modelling elastic and inelastic photon-initiated production at the LHC: SuperChic 4

Collinear electroweak radiation in antenna parton showers

NLO QCD+EW predictions for tHj and tZj production at the LHC

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