Showing total 5 results

1. Impact of scale, nuclear PDF and temperature variations on the interpretation of medium-modified jet production data from the LHC.

Author

Andronic, A., Honermann, J., Klasen, M., Klein-Bösing, C., and Salomon, J.

Subjects

DISTRIBUTION (Probability theory), TEMPERATURE, UNCERTAINTY, HEAVY ions

Abstract

In this paper we present a study of in-medium jet modifications performed with JEWEL and PYTHIA 6.4, focusing on the uncertainties related to variations of the perturbative scales and nuclear parton distribution functions (PDFs) and on the impact of the initial and crossover temperature variations of the medium. The simulations are compared to LHC data for the jet spectrum and the nuclear modification factor. We assess the interplay between the choice of nuclear PDFs and different medium parameters and study the impact of nuclear PDFs and the medium on the jet structure via the Lund plane. [ABSTRACT FROM AUTHOR]

Published

2021

2. Lund and Cambridge multiplicities for precision physics.

Author

Medves, Rok, Soto-Ontoso, Alba, and Soyez, Gregory

Subjects

MONTE Carlo method, MULTIPLICITY (Mathematics), POSITRON annihilation, HADRONIC atoms

Abstract

We revisit the calculation of the average jet multiplicity in high-energy collisions. First, we introduce a new definition of (sub)jet multiplicity based on Lund declusterings obtained using the Cambridge jet algorithm. We develop a new systematic resummation approach. This allows us to compute both the Lund and the Cambridge average multiplicities to next-to-next-to-double (NNDL) logarithmic accuracy in electron-positron annihilation, an order higher in accuracy than previous works in the literature. We match our resummed calculation to the exact NLO (O ( α s 2 )) result, showing predictions for the Lund multiplicity at LEP energies with theoretical uncertainties up to 50% smaller than the previous state-of-the-art. Adding hadronisation corrections obtained by Monte Carlo simulations, we also show a good agreement with existing Cambridge multiplicity data. Finally, to highlight the flexibility of our method, we extend the Lund multiplicity calculation to hadronic collisions where we reach next-to-double logarithmic accuracy for colour singlet production. [ABSTRACT FROM AUTHOR]

Published

2022

3. Jet tagging in the Lund plane with graph networks.

Author

Dreyer, Frédéric A. and Qu, Huilin

Subjects

LARGE Hadron Collider, TOP quarks, COMPUTATIONAL complexity, MAGNITUDE (Mathematics), BOSONS

Abstract

The identification of boosted heavy particles such as top quarks or vector bosons is one of the key problems arising in experimental studies at the Large Hadron Collider. In this article, we introduce LundNet, a novel jet tagging method which relies on graph neural networks and an efficient description of the radiation patterns within a jet to optimally disentangle signatures of boosted objects from background events. We apply this framework to a number of different benchmarks, showing significantly improved performance for top tagging compared to existing state-of-the-art algorithms. We study the robustness of the LundNet taggers to non-perturbative and detector effects, and show how kinematic cuts in the Lund plane can mitigate overfitting of the neural network to model-dependent contributions. Finally, we consider the computational complexity of this method and its scaling as a function of kinematic Lund plane cuts, showing an order of magnitude improvement in speed over previous graph-based taggers. [ABSTRACT FROM AUTHOR]

Published

2021

4. Colour and logarithmic accuracy in final-state parton showers.

Author

Hamilton, Keith, Medves, Rok, Salam, Gavin P., Scyboz, Ludovic, and Soyez, Gregory

Subjects

LOGARITHMS, PARTONS, MULTIPLICITY (Mathematics), MEDICAL prescriptions, QUANTUM chromodynamics, COLOR

Abstract

Standard dipole parton showers are known to yield incorrect subleading-colour contributions to the leading (double) logarithmic terms for a variety of observables. In this work, concentrating on final-state showers, we present two simple, computationally efficient prescriptions to correct this problem, exploiting a Lund-diagram type classification of emission regions. We study the resulting effective multiple-emission matrix elements generated by the shower, and discuss their impact on subleading colour contributions to leading and next-to-leading logarithms (NLL) for a range of observables. In particular we show that the new schemes give the correct full colour NLL terms for global observables and multiplicities. Subleading colour issues remain at NLL (single logarithms) for non-global observables, though one of our two schemes reproduces the correct full-colour matrix-element for any number of energy-ordered commensurate-angle pairs of emissions. While we carry out our tests within the PanScales shower framework, the schemes are sufficiently simple that it should be straightforward to implement them also in other shower frameworks. [ABSTRACT FROM AUTHOR]

Published

2021

5. Modification of jet substructure in heavy ion collisions as a probe of the resolution length of quark-gluon plasma.

Author

Casalderrey-Solana, J., Milhano, G., Pablos, D., and Rajagopal, K.

Subjects

HEAVY ion collisions, QUARK-gluon plasma, PLASMA jets, PHASE space

Abstract

We present an analysis of the role that the quark-gluon plasma (QGP) resolution length, the minimal distance by which two nearby colored charges in a jet must be separated such that they engage with the plasma independently, plays in understanding the modification of jet substructure due to interaction with QGP. The shorter the resolution length of QGP, the better its resolving power. We identify a set of observables that are sen- sitive to whether jets are quenched as if they are single energetic colored objects or whether the medium that quenches them has the ability to resolve the internal structure of the jet. Using the hybrid strong/weak coupling model, we find that although the ungroomed jet mass is not suitable for this purpose (because it is more sensitive to effects coming from particles reconstructed as a part of a jet that originate from the wake that the jet leaves in the plasma), groomed observables such as the number of Soft Drop splittings nSD, the momentum sharing fraction zg, or the groomed jet mass are particularly well-suited to discriminate the degree to which the QGP medium resolves substructure within a jet. In order to find the optimal grooming strategy, we explore different cuts in the Lund plane that allow for a clear identification of the regions of Soft Drop phase space that enhance the differences in the jet substructure between jets in vacuum and quenched jets. Comparison with present data seems to disfavor an "infinite resolution length", which is to say the hypothesis that the medium interacts with the jet as if it were a single energetic colored object. Our analysis indicates that as the precision of experimental measurements of jet substructure observables and the control over uncertainties in their calculation improves, it will become possible to use comparisons like this to constrain the value of the resolution length of QGP, in addition to seeing how the substructure of jets is modified via their passage through it. [ABSTRACT FROM AUTHOR]

Published

2020