Abstract
We study jet angularities for dijet production at the Relativistic Heavy Ion Collider (RHIC) in proton-proton (pp) and nucleus-nucleus (AA) collisions at 200 GeV nucleon-nucleon center-of-mass collision energy. In particular, we provide NLL resummed predictions for angularity observables of groomed and ungroomed jets produced in pp collisions matched to next-to-leading order QCD calculations resulting in NLO + NLL′ accuracy. Our parton-level predictions are corrected for non-perturbative effects, such as hadronization and underlying event, using parton-to-hadron level transfer matrices obtained with the Sherpa event generator. Furthermore, we use the Q-Pythia and Jewel generators to estimate the impact of the interaction between quarks and gluons produced by the parton shower with the dense medium formed in heavy-ion collisions on the considered jet angularities.
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References
D. Britzger et al., Determination of the strong coupling constant using inclusive jet cross section data from multiple experiments, Eur. Phys. J. C 79 (2019) 68 [arXiv:1712.00480] [INSPIRE].
CMS collaboration, Measurement of the Ratio of the Inclusive 3-Jet Cross Section to the Inclusive 2-Jet Cross Section in pp Collisions at \( \sqrt{s} \) = 7 TeV and First Determination of the Strong Coupling Constant in the TeV Range, Eur. Phys. J. C 73 (2013) 2604 [arXiv:1304.7498] [INSPIRE].
ATLAS collaboration, Determination of the strong coupling constant αs from transverse energy-energy correlations in multijet events at \( \sqrt{s} \) = 8 TeV using the ATLAS detector, Eur. Phys. J. C 77 (2017) 872 [arXiv:1707.02562] [INSPIRE].
ATLAS collaboration, Measurement of transverse energy-energy correlations in multi-jet events in pp collisions at \( \sqrt{s} \) = 7 TeV using the ATLAS detector and determination of the strong coupling constant αs(mZ), Phys. Lett. B 750 (2015) 427 [arXiv:1508.01579] [INSPIRE].
CMS collaboration, Measurement of the inclusive 3-jet production differential cross section in proton-proton collisions at 7 TeV and determination of the strong coupling constant in the TeV range, Eur. Phys. J. C 75 (2015) 186 [arXiv:1412.1633] [INSPIRE].
ATLAS collaboration, Determination of the parton distribution functions of the proton from ATLAS measurements of differential W± and Z boson production in association with jets, JHEP 07 (2021) 223 [arXiv:2101.05095] [INSPIRE].
ATLAS collaboration, Measurement of the inclusive jet cross section in pp collisions at sqrt(s)=2.76 TeV and comparison to the inclusive jet cross section at sqrt(s)=7 TeV using the ATLAS detector, Eur. Phys. J. C 73 (2013) 2509 [arXiv:1304.4739] [INSPIRE].
CMS collaboration, Constraints on parton distribution functions and extraction of the strong coupling constant from the inclusive jet cross section in pp collisions at \( \sqrt{s} \) = 7 TeV, Eur. Phys. J. C 75 (2015) 288 [arXiv:1410.6765] [INSPIRE].
CMS collaboration, Measurement and QCD analysis of double-differential inclusive jet cross sections in pp collisions at \( \sqrt{s} \) = 8 TeV and cross section ratios to 2.76 and 7 TeV, JHEP 03 (2017) 156 [arXiv:1609.05331] [INSPIRE].
R. Abdul Khalek et al., Phenomenology of NNLO jet production at the LHC and its impact on parton distributions, Eur. Phys. J. C 80 (2020) 797 [arXiv:2005.11327] [INSPIRE].
L.A. Harland-Lang, A.D. Martin and R.S. Thorne, The Impact of LHC Jet Data on the MMHT PDF Fit at NNLO, Eur. Phys. J. C 78 (2018) 248 [arXiv:1711.05757] [INSPIRE].
J. Pumplin et al., Collider Inclusive Jet Data and the Gluon Distribution, Phys. Rev. D 80 (2009) 014019 [arXiv:0904.2424] [INSPIRE].
B.J.A. Watt, P. Motylinski and R.S. Thorne, The Effect of LHC Jet Data on MSTW PDFs, Eur. Phys. J. C 74 (2014) 2934 [arXiv:1311.5703] [INSPIRE].
CMS collaboration, Study of quark and gluon jet substructure in Z+jet and dijet events from pp collisions, JHEP 01 (2022) 188 [arXiv:2109.03340] [INSPIRE].
ALICE collaboration, Measurements of the groomed and ungroomed jet angularities in pp collisions at \( \sqrt{s} \) = 5.02 TeV, JHEP 05 (2022) 061 [arXiv:2107.11303] [INSPIRE].
D.E. Soper and M. Spannowsky, Combining subjet algorithms to enhance ZH detection at the LHC, JHEP 08 (2010) 029 [arXiv:1005.0417] [INSPIRE].
R.M. Godbole, D.J. Miller, K.A. Mohan and C.D. White, Jet substructure and probes of CP violation in Vh production, JHEP 04 (2015) 103 [arXiv:1409.5449] [INSPIRE].
N. Chen, J. Li, Y. Liu and Z. Liu, LHC searches for the CP-odd Higgs by the jet substructure analysis, Phys. Rev. D 91 (2015) 075002 [arXiv:1410.4447] [INSPIRE].
D. Adams et al., Towards an Understanding of the Correlations in Jet Substructure, Eur. Phys. J. C 75 (2015) 409 [arXiv:1504.00679] [INSPIRE].
A.J. Larkoski, I. Moult and B. Nachman, Jet Substructure at the Large Hadron Collider: a Review of Recent Advances in Theory and Machine Learning, Phys. Rept. 841 (2020) 1 [arXiv:1709.04464] [INSPIRE].
A. Butter et al., The Machine Learning landscape of top taggers, SciPost Phys. 7 (2019) 014 [arXiv:1902.09914] [INSPIRE].
L. Benato et al., Teaching machine learning with an application in collider particle physics, 2020 JINST 15 C09011 [INSPIRE].
O. Fedkevych, C.K. Khosa, S. Marzani and F. Sforza, Identification of b jets using QCD-inspired observables, Phys. Rev. D 107 (2023) 034032 [arXiv:2202.05082] [INSPIRE].
S. Caletti, O. Fedkevych, S. Marzani and D. Reichelt, Tagging the initial-state gluon, Eur. Phys. J. C 81 (2021) 844 [arXiv:2108.10024] [INSPIRE].
F.A. Dreyer, G. Soyez and A. Takacs, Quarks and gluons in the Lund plane, JHEP 08 (2022) 177 [arXiv:2112.09140] [INSPIRE].
L. Cavallini et al., Tagging the Higgs boson decay to bottom quarks with colour-sensitive observables and the Lund jet plane, Eur. Phys. J. C 82 (2022) 493 [arXiv:2112.09650] [INSPIRE].
C.K. Khosa and S. Marzani, Higgs boson tagging with the Lund jet plane, Phys. Rev. D 104 (2021) 055043 [arXiv:2105.03989] [INSPIRE].
F.A. Dreyer and H. Qu, Jet tagging in the Lund plane with graph networks, JHEP 03 (2021) 052 [arXiv:2012.08526] [INSPIRE].
P. Baroň, M.H. Seymour and A. Siódmok, Novel approach to measure quark/gluon jets at the LHC, Eur. Phys. J. C 84 (2024) 28 [arXiv:2307.15378] [INSPIRE].
K. Lapidus and M.H. Oliver, Hard Substructure of Quenched Jets: a Monte Carlo Study, arXiv:1711.00897 [INSPIRE].
K.C. Zapp, Jet energy loss and equilibration, Nucl. Phys. A 967 (2017) 81 [INSPIRE].
K. Tywoniuk and Y. Mehtar-Tani, Measuring medium-induced gluons via jet grooming, Nucl. Phys. A 967 (2017) 520 [INSPIRE].
J. Casalderrey-Solana, Y. Mehtar-Tani, C.A. Salgado and K. Tywoniuk, Probing jet decoherence in heavy ion collisions, Nucl. Phys. A 967 (2017) 564 [INSPIRE].
J. Casalderrey-Solana, G. Milhano, D. Pablos and K. Rajagopal, Modification of Jet Substructure in Heavy Ion Collisions as a Probe of the Resolution Length of Quark-Gluon Plasma, JHEP 01 (2020) 044 [arXiv:1907.11248] [INSPIRE].
M.L. Mangano and B. Nachman, Observables for possible QGP signatures in central pp collisions, Eur. Phys. J. C 78 (2018) 343 [arXiv:1708.08369] [INSPIRE].
G.-Y. Qin, Modification of jet rate, shape and structure: model and phenomenology, Nucl. Part. Phys. Proc. 289-290 (2017) 47 [INSPIRE].
G. Milhano, U.A. Wiedemann and K.C. Zapp, Sensitivity of jet substructure to jet-induced medium response, Phys. Lett. B 779 (2018) 409 [arXiv:1707.04142] [INSPIRE].
N.-B. Chang, S. Cao and G.-Y. Qin, Probing medium-induced jet splitting and energy loss in heavy-ion collisions, Phys. Lett. B 781 (2018) 423 [arXiv:1707.03767] [INSPIRE].
R. Kunnawalkam Elayavalli and K.C. Zapp, Medium response in JEWEL and its impact on jet shape observables in heavy ion collisions, JHEP 07 (2017) 141 [arXiv:1707.01539] [INSPIRE].
P. Caucal, E. Iancu and G. Soyez, Deciphering the zg distribution in ultrarelativistic heavy ion collisions, JHEP 10 (2019) 273 [arXiv:1907.04866] [INSPIRE].
P. Caucal, E. Iancu and G. Soyez, Jet radiation in a longitudinally expanding medium, JHEP 04 (2021) 209 [arXiv:2012.01457] [INSPIRE].
P. Caucal, A. Soto-Ontoso and A. Takacs, Dynamically groomed jet radius in heavy-ion collisions, Phys. Rev. D 105 (2022) 114046 [arXiv:2111.14768] [INSPIRE].
L. Cunqueiro et al., Isolating perturbative QCD splittings in heavy-ion collisions, Phys. Rev. D 110 (2024) 014015 [arXiv:2311.07643] [INSPIRE].
ALICE collaboration, First measurement of jet mass in Pb–Pb and p–Pb collisions at the LHC, Phys. Lett. B 776 (2018) 249 [arXiv:1702.00804] [INSPIRE].
ALICE collaboration, Medium modification of the shape of small-radius jets in central Pb-Pb collisions at \( \sqrt{s_{NN}} \) = 2.76 TeV, JHEP 10 (2018) 139 [arXiv:1807.06854] [INSPIRE].
CMS collaboration, Dijet Azimuthal Decorrelations in pp Collisions at \( \sqrt{s} \) = 7TeV, Phys. Rev. Lett. 106 (2011) 122003 [arXiv:1101.5029] [INSPIRE].
CMS collaboration, Modification of Jet Shapes in PbPb Collisions at \( \sqrt{s_{NN}} \) = 2.76 TeV, Phys. Lett. B 730 (2014) 243 [arXiv:1310.0878] [INSPIRE].
CMS collaboration, Studies of Jet Mass in Dijet and W/Z + Jet Events, JHEP 05 (2013) 090 [arXiv:1303.4811] [INSPIRE].
CMS collaboration, Event Shapes and Azimuthal Correlations in Z + Jets Events in pp Collisions at \( \sqrt{s} \) = 7 TeV, Phys. Lett. B 722 (2013) 238 [arXiv:1301.1646] [INSPIRE].
CMS collaboration, Studies of dijet transverse momentum balance and pseudorapidity distributions in pPb collisions at \( \sqrt{s_{\textrm{NN}}} \) = 5.02 TeV, Eur. Phys. J. C 74 (2014) 2951 [arXiv:1401.4433] [INSPIRE].
CMS collaboration, Measurements of differential production cross sections for a Z boson in association with jets in pp collisions at \( \sqrt{s} \) = 8 TeV, JHEP 04 (2017) 022 [arXiv:1611.03844] [INSPIRE].
CMS collaboration, Study of Jet Quenching with Z + jet Correlations in Pb-Pb and pp Collisions at \( \sqrt{s_{NN}} \) = 5.02 TeV, Phys. Rev. Lett. 119 (2017) 082301 [arXiv:1702.01060] [INSPIRE].
CMS collaboration, Measurement of the jet mass in highly boosted \( \textrm{t}\overline{\textrm{t}} \) events from pp collisions at \( \sqrt{s} \) = 8 TeV, Eur. Phys. J. C 77 (2017) 467 [arXiv:1703.06330] [INSPIRE].
CMS collaboration, Observation of Medium-Induced Modifications of Jet Fragmentation in Pb-Pb Collisions at \( \sqrt{s_{NN}} \) = 5.02 TeV Using Isolated Photon-Tagged Jets, Phys. Rev. Lett. 121 (2018) 242301 [arXiv:1801.04895] [INSPIRE].
CMS collaboration, Measurement of the groomed jet mass in PbPb and pp collisions at \( \sqrt{s_{\textrm{NN}}} \) = 5.02 TeV, JHEP 10 (2018) 161 [arXiv:1805.05145] [INSPIRE].
CMS collaboration, Measurements of the differential jet cross section as a function of the jet mass in dijet events from proton-proton collisions at \( \sqrt{s} \) = 13 TeV, JHEP 11 (2018) 113 [arXiv:1807.05974] [INSPIRE].
CMS collaboration, Measurement of jet substructure observables in \( \textrm{t}\overline{\textrm{t}} \) events from proton-proton collisions at \( \sqrt{s} \) = 13TeV, Phys. Rev. D 98 (2018) 092014 [arXiv:1808.07340] [INSPIRE].
CMS collaboration, Measurement of the Jet Mass Distribution and Top Quark Mass in Hadronic Decays of Boosted Top Quarks in pp Collisions at \( \sqrt{s} \) = TeV, Phys. Rev. Lett. 124 (2020) 202001 [arXiv:1911.03800] [INSPIRE].
ATLAS collaboration, Measurement of Dijet Azimuthal Decorrelations in pp Collisions at \( \sqrt{s} \) = 7 TeV, Phys. Rev. Lett. 106 (2011) 172002 [arXiv:1102.2696] [INSPIRE].
ATLAS collaboration, ATLAS Measurements of the Properties of Jets for Boosted Particle Searches, Phys. Rev. D 86 (2012) 072006 [arXiv:1206.5369] [INSPIRE].
ATLAS collaboration, Jet mass and substructure of inclusive jets in \( \sqrt{s} \) = 7 TeV pp collisions with the ATLAS experiment, JHEP 05 (2012) 128 [arXiv:1203.4606] [INSPIRE].
ATLAS collaboration, Measurements of jet vetoes and azimuthal decorrelations in dijet events produced in pp collisions at \( \sqrt{s} \) = 7 TeV using the ATLAS detector, Eur. Phys. J. C 74 (2014) 3117 [arXiv:1407.5756] [INSPIRE].
ATLAS collaboration, Measurement of jet fragmentation in Pb+Pb and pp collisions at \( \sqrt{s_{\textrm{NN}}} \) = 2.76 TeV with the ATLAS detector at the LHC, Eur. Phys. J. C 77 (2017) 379 [arXiv:1702.00674] [INSPIRE].
ATLAS collaboration, Measurement of the Soft-Drop Jet Mass in pp Collisions at \( \sqrt{s} \) = 13 TeV with the ATLAS Detector, Phys. Rev. Lett. 121 (2018) 092001 [arXiv:1711.08341] [INSPIRE].
ATLAS collaboration, Measurement of the cross section for isolated-photon plus jet production in pp collisions at \( \sqrt{s} \) = 13 TeV using the ATLAS detector, Phys. Lett. B 780 (2018) 578 [arXiv:1801.00112] [INSPIRE].
ATLAS collaboration, Measurement of R = 0.4 jet mass in Pb+Pb and pp collisions at \( \sqrt{s_{\textrm{NN}}} \) = 5.02 TeV with the ATLAS detector, ATLAS-CONF-2018-014, CERN, Geneva (2018).
ATLAS collaboration, Measurement of the jet mass in high transverse momentum \( Z\left(\to b\overline{b}\right)\gamma \) production at \( \sqrt{s} \) = 13 TeV using the ATLAS detector, Phys. Lett. B 812 (2021) 135991 [arXiv:1907.07093] [INSPIRE].
ATLAS collaboration, Measurement of soft-drop jet observables in pp collisions with the ATLAS detector at \( \sqrt{s} \) = 13 TeV, Phys. Rev. D 101 (2020) 052007 [arXiv:1912.09837] [INSPIRE].
STAR collaboration, Measurement of the Shared Momentum Fraction zg using Jet Reconstruction in p+p and Au+Au Collisions with STAR, Nucl. Phys. A 967 (2017) 516 [arXiv:1704.03046] [INSPIRE].
STAR collaboration, Measurement of groomed jet substructure observables in p+p collisions at \( \sqrt{s} \) = 200 GeV with STAR, Phys. Lett. B 811 (2020) 135846 [arXiv:2003.02114] [INSPIRE].
STAR collaboration, Invariant Jet Mass Measurements in pp Collisions at \( \sqrt{s} \) = 200 GeV at RHIC, Phys. Rev. D 104 (2021) 052007 [arXiv:2103.13286] [INSPIRE].
M. Connors, C. Nattrass, R. Reed and S. Salur, Jet measurements in heavy ion physics, Rev. Mod. Phys. 90 (2018) 025005 [arXiv:1705.01974] [INSPIRE].
A. Moraes, C. Buttar and I. Dawson, Prediction for minimum bias and the underlying event at LHC energies, Eur. Phys. J. C 50 (2007) 435 [INSPIRE].
C. Bierlich et al., A comprehensive guide to the physics and usage of PYTHIA 8.3, SciPost Phys. Codeb. 2022 (2022) 8 [arXiv:2203.11601] [INSPIRE].
T. Sjostrand, S. Mrenna and P.Z. Skands, PYTHIA 6.4 Physics and Manual, JHEP 05 (2006) 026 [hep-ph/0603175] [INSPIRE].
J. Bellm et al., Herwig 7.2 release note, Eur. Phys. J. C 80 (2020) 452 [arXiv:1912.06509] [INSPIRE].
G. Corcella et al., HERWIG 6: an event generator for hadron emission reactions with interfering gluons (including supersymmetric processes), JHEP 01 (2001) 010 [hep-ph/0011363] [INSPIRE].
Sherpa collaboration, Event Generation with Sherpa 2.2, SciPost Phys. 7 (2019) 034 [arXiv:1905.09127] [INSPIRE].
T. Gleisberg et al., Event generation with SHERPA 1.1, JHEP 02 (2009) 007 [arXiv:0811.4622] [INSPIRE].
M.R. Aguilar et al., pythia8 underlying event tune for RHIC energies, Phys. Rev. D 105 (2022) 016011 [arXiv:2110.09447] [INSPIRE].
D. Reichelt et al., Phenomenology of jet angularities at the LHC, JHEP 03 (2022) 131 [arXiv:2112.09545] [INSPIRE].
C.F. Berger, T. Kucs and G.F. Sterman, Event shape / energy flow correlations, Phys. Rev. D 68 (2003) 014012 [hep-ph/0303051] [INSPIRE].
L.G. Almeida et al., Substructure of high-pT Jets at the LHC, Phys. Rev. D 79 (2009) 074017 [arXiv:0807.0234] [INSPIRE].
A.J. Larkoski, J. Thaler and W.J. Waalewijn, Gaining (Mutual) Information about Quark/Gluon Discrimination, JHEP 11 (2014) 129 [arXiv:1408.3122] [INSPIRE].
CDF collaboration, Study of Substructure of High Transverse Momentum Jets Produced in Proton-Antiproton Collisions at \( \sqrt{s} \) = 1.96 TeV, Phys. Rev. D 85 (2012) 091101 [arXiv:1106.5952] [INSPIRE].
S. Marzani, G. Soyez and M. Spannowsky, Looking inside jets: an introduction to jet substructure and boosted-object phenomenology, Springer (2019) [https://doi.org/10.1007/978-3-030-15709-8] [INSPIRE].
S. Caletti et al., Jet angularities in Z+jet production at the LHC, JHEP 07 (2021) 076 [arXiv:2104.06920] [INSPIRE].
Z.-B. Kang, K. Lee and F. Ringer, Jet angularity measurements for single inclusive jet production, JHEP 04 (2018) 110 [arXiv:1801.00790] [INSPIRE].
Z.-B. Kang, K. Lee, X. Liu and F. Ringer, Soft drop groomed jet angularities at the LHC, Phys. Lett. B 793 (2019) 41 [arXiv:1811.06983] [INSPIRE].
L.G. Almeida et al., Comparing and counting logs in direct and effective methods of QCD resummation, JHEP 04 (2014) 174 [arXiv:1401.4460] [INSPIRE].
M. Dasgupta, B.K. El-Menoufi and J. Helliwell, QCD resummation for groomed jet observables at NNLL+NLO, JHEP 01 (2023) 045 [arXiv:2211.03820] [INSPIRE].
A. Budhraja, R. Sharma and B. Singh, Medium modifications to jet angularities using SCET with Glauber gluons, arXiv:2305.10237 [INSPIRE].
E. Gerwick, S. Hoeche, S. Marzani and S. Schumann, Soft evolution of multi-jet final states, JHEP 02 (2015) 106 [arXiv:1411.7325] [INSPIRE].
N. Baberuxki, C.T. Preuss, D. Reichelt and S. Schumann, Resummed predictions for jet-resolution scales in multijet production in e+e− annihilation, JHEP 04 (2020) 112 [arXiv:1912.09396] [INSPIRE].
sPHENIX collaboration, Status and Performance of sPHENIX Experiment, EPJ Web Conf. 276 (2023) 05004 [INSPIRE].
N. Armesto, L. Cunqueiro and C.A. Salgado, Q-PYTHIA: a Medium-modified implementation of final state radiation, Eur. Phys. J. C 63 (2009) 679 [arXiv:0907.1014] [INSPIRE].
K. Zapp et al., A Monte Carlo Model for ‘Jet Quenching’, Eur. Phys. J. C 60 (2009) 617 [arXiv:0804.3568] [INSPIRE].
K.C. Zapp, JEWEL 2.0.0: directions for use, Eur. Phys. J. C 74 (2014) 2762 [arXiv:1311.0048] [INSPIRE].
M. Cacciari, G.P. Salam and G. Soyez, FastJet User Manual, Eur. Phys. J. C 72 (2012) 1896 [arXiv:1111.6097] [INSPIRE].
M. Cacciari, G.P. Salam and G. Soyez, The anti-kt jet clustering algorithm, JHEP 04 (2008) 063 [arXiv:0802.1189] [INSPIRE].
J. Currie et al., Infrared sensitivity of single jet inclusive production at hadron colliders, JHEP 10 (2018) 155 [arXiv:1807.03692] [INSPIRE].
J.R. Andersen et al., Les Houches 2015: physics at TeV Colliders Standard Model Working Group Report, in the proceedings of the 9th Les Houches Workshop on Physics at TeV Colliders, Les Houches, France, June 01–19 (2015) [arXiv:1605.04692] [INSPIRE].
A. Banfi, G.P. Salam and G. Zanderighi, Principles of general final-state resummation and automated implementation, JHEP 03 (2005) 073 [hep-ph/0407286] [INSPIRE].
A.J. Larkoski, G.P. Salam and J. Thaler, Energy Correlation Functions for Jet Substructure, JHEP 06 (2013) 108 [arXiv:1305.0007] [INSPIRE].
A.J. Larkoski, D. Neill and J. Thaler, Jet Shapes with the Broadening Axis, JHEP 04 (2014) 017 [arXiv:1401.2158] [INSPIRE].
A. Budhraja, A. Jain and M. Procura, One-loop angularity distributions with recoil using Soft-Collinear Effective Theory, JHEP 08 (2019) 144 [arXiv:1903.11087] [INSPIRE].
S. Marzani, L. Schunk and G. Soyez, A study of jet mass distributions with grooming, JHEP 07 (2017) 132 [arXiv:1704.02210] [INSPIRE].
A.J. Larkoski, S. Marzani, G. Soyez and J. Thaler, Soft Drop, JHEP 05 (2014) 146 [arXiv:1402.2657] [INSPIRE].
Y.L. Dokshitzer, G.D. Leder, S. Moretti and B.R. Webber, Better jet clustering algorithms, JHEP 08 (1997) 001 [hep-ph/9707323] [INSPIRE].
M. Wobisch and T. Wengler, Hadronization corrections to jet cross-sections in deep inelastic scattering, in the proceedings of the Workshop on Monte Carlo Generators for HERA Physics (Plenary Starting Meeting), Hamburg, Germany, April 27–30 (1998) [hep-ph/9907280] [INSPIRE].
A. Buckley et al., Rivet user manual, Comput. Phys. Commun. 184 (2013) 2803 [arXiv:1003.0694] [INSPIRE].
C. Bierlich et al., Robust Independent Validation of Experiment and Theory: Rivet version 3, SciPost Phys. 8 (2020) 026 [arXiv:1912.05451] [INSPIRE].
J.D. Hunter, Matplotlib: a 2D Graphics Environment, Comput. Sci. Eng. 9 (2007) 90 [INSPIRE].
A. Banfi, G.P. Salam and G. Zanderighi, Phenomenology of event shapes at hadron colliders, JHEP 06 (2010) 038 [arXiv:1001.4082] [INSPIRE].
G. Luisoni and S. Marzani, QCD resummation for hadronic final states, J. Phys. G 42 (2015) 103101 [arXiv:1505.04084] [INSPIRE].
S. Marzani et al., Fitting the Strong Coupling Constant with Soft-Drop Thrust, JHEP 11 (2019) 179 [arXiv:1906.10504] [INSPIRE].
J. Baron et al., Soft-drop grooming for hadronic event shapes, JHEP 07 (2021) 142 [arXiv:2012.09574] [INSPIRE].
M. Knobbe, D. Reichelt and S. Schumann, (N)NLO+NLL’ accurate predictions for plain and groomed 1-jettiness in neutral current DIS, JHEP 09 (2023) 194 [arXiv:2306.17736] [INSPIRE].
H1 collaboration, Measurement of the 1-jettiness event shape observable in deep-inelastic electron-proton scattering at HERA, arXiv:2403.10109 [INSPIRE].
H1 collaboration, Measurement of groomed event shape observables in deep-inelastic electron-proton scattering at HERA, arXiv:2403.10134 [INSPIRE].
A. Gehrmann-De Ridder, C.T. Preuss, D. Reichelt and S. Schumann, NLO+NLL’ accurate predictions for three-jet event shapes in hadronic Higgs decays, arXiv:2403.06929 [INSPIRE].
M. Dasgupta and G.P. Salam, Resummation of nonglobal QCD observables, Phys. Lett. B 512 (2001) 323 [hep-ph/0104277] [INSPIRE].
M. Dasgupta, K. Khelifa-Kerfa, S. Marzani and M. Spannowsky, On jet mass distributions in Z+jet and dijet processes at the LHC, JHEP 10 (2012) 126 [arXiv:1207.1640] [INSPIRE].
M. Dasgupta, A. Fregoso, S. Marzani and G.P. Salam, Towards an understanding of jet substructure, JHEP 09 (2013) 029 [arXiv:1307.0007] [INSPIRE].
T. Gleisberg and S. Hoeche, Comix, a new matrix element generator, JHEP 12 (2008) 039 [arXiv:0808.3674] [INSPIRE].
T. Gleisberg and F. Krauss, Automating dipole subtraction for QCD NLO calculations, Eur. Phys. J. C 53 (2008) 501 [arXiv:0709.2881] [INSPIRE].
S. Actis et al., RECOLA: REcursive Computation of One-Loop Amplitudes, Comput. Phys. Commun. 214 (2017) 140 [arXiv:1605.01090] [INSPIRE].
B. Biedermann et al., Automation of NLO QCD and EW corrections with Sherpa and Recola, Eur. Phys. J. C 77 (2017) 492 [arXiv:1704.05783] [INSPIRE].
F. Cascioli, P. Maierhofer and S. Pozzorini, Scattering Amplitudes with Open Loops, Phys. Rev. Lett. 108 (2012) 111601 [arXiv:1111.5206] [INSPIRE].
S. Caletti, A.J. Larkoski, S. Marzani and D. Reichelt, A fragmentation approach to jet flavor, JHEP 10 (2022) 158 [arXiv:2205.01117] [INSPIRE].
S. Caletti, A.J. Larkoski, S. Marzani and D. Reichelt, Practical jet flavour through NNLO, Eur. Phys. J. C 82 (2022) 632 [arXiv:2205.01109] [INSPIRE].
M. Czakon, A. Mitov and R. Poncelet, Infrared-safe flavoured anti-kT jets, JHEP 04 (2023) 138 [arXiv:2205.11879] [INSPIRE].
R. Gauld, A. Huss and G. Stagnitto, Flavor Identification of Reconstructed Hadronic Jets, Phys. Rev. Lett. 130 (2023) 161901 [Erratum ibid. 132 (2024) 159901] [arXiv:2208.11138] [INSPIRE].
F. Caola et al., Flavored jets with exact anti-kt kinematics and tests of infrared and collinear safety, Phys. Rev. D 108 (2023) 094010 [arXiv:2306.07314] [INSPIRE].
J. Andersen et al., Les Houches 2023: physics at TeV Colliders: standard Model Working Group Report, in the proceedings of the Physics of the TeV Scale and Beyond the Standard Model: Intensifying the Quest for New Physics, Les Houches, France, June 12–30 (2023) [arXiv:2406.00708] [INSPIRE].
A. Banfi, G.P. Salam and G. Zanderighi, Infrared safe definition of jet flavor, Eur. Phys. J. C 47 (2006) 113 [hep-ph/0601139] [INSPIRE].
PDF4LHC Working Group collaboration, The PDF4LHC21 combination of global PDF fits for the LHC Run III, J. Phys. G 49 (2022) 080501 [arXiv:2203.05506] [INSPIRE].
A. Buckley et al., LHAPDF6: parton density access in the LHC precision era, Eur. Phys. J. C 75 (2015) 132 [arXiv:1412.7420] [INSPIRE].
E. Bothmann, M. Schönherr and S. Schumann, Reweighting QCD matrix-element and parton-shower calculations, Eur. Phys. J. C 76 (2016) 590 [arXiv:1606.08753] [INSPIRE].
A. Buckley et al., General-purpose event generators for LHC physics, Phys. Rept. 504 (2011) 145 [arXiv:1101.2599] [INSPIRE].
J.M. Campbell et al., Event Generators for High-Energy Physics Experiments, SciPost Phys. 16 (2024) 130 [arXiv:2203.11110] [INSPIRE].
A.V. Manohar and M.B. Wise, Power suppressed corrections to hadronic event shapes, Phys. Lett. B 344 (1995) 407 [hep-ph/9406392] [INSPIRE].
Y.L. Dokshitzer and B.R. Webber, Calculation of power corrections to hadronic event shapes, Phys. Lett. B 352 (1995) 451 [hep-ph/9504219] [INSPIRE].
R. Akhoury and V.I. Zakharov, On the universality of the leading, 1/Q power corrections in QCD, Phys. Lett. B 357 (1995) 646 [hep-ph/9504248] [INSPIRE].
G.P. Korchemsky and G.F. Sterman, Universality of infrared renormalons in hadronic cross-sections, in the proceedings of the 30th Rencontres de Moriond: QCD and High-energy Hadronic Interactions, Les Arcs, France, March 19–25 (1995) [hep-ph/9505391] [INSPIRE].
Y.L. Dokshitzer, G. Marchesini and G.P. Salam, Revisiting nonperturbative effects in the jet broadenings, Eur. Phys. J. direct 1 (1999) 3 [hep-ph/9812487] [INSPIRE].
S. Hoeche, F. Krauss, M. Schonherr and F. Siegert, QCD matrix elements + parton showers: the NLO case, JHEP 04 (2013) 027 [arXiv:1207.5030] [INSPIRE].
S. Schumann and F. Krauss, A parton shower algorithm based on Catani-Seymour dipole factorisation, JHEP 03 (2008) 038 [arXiv:0709.1027] [INSPIRE].
A. Denner, S. Dittmaier and L. Hofer, Collier: a fortran-based Complex One-Loop LIbrary in Extended Regularizations, Comput. Phys. Commun. 212 (2017) 220 [arXiv:1604.06792] [INSPIRE].
T. Sjostrand and M. van Zijl, A Multiple Interaction Model for the Event Structure in Hadron Collisions, Phys. Rev. D 36 (1987) 2019 [INSPIRE].
G.S. Chahal and F. Krauss, Cluster Hadronisation in Sherpa, SciPost Phys. 13 (2022) 019 [arXiv:2203.11385] [INSPIRE].
M. Knobbe, F. Krauss, D. Reichelt and S. Schumann, Measuring hadronic Higgs boson branching ratios at future lepton colliders, Eur. Phys. J. C 84 (2024) 83 [arXiv:2306.03682] [INSPIRE].
T. Sjostrand and P.Z. Skands, Transverse-momentum-ordered showers and interleaved multiple interactions, Eur. Phys. J. C 39 (2005) 129 [hep-ph/0408302] [INSPIRE].
R. Corke and T. Sjostrand, Interleaved Parton Showers and Tuning Prospects, JHEP 03 (2011) 032 [arXiv:1011.1759] [INSPIRE].
P. Skands, S. Carrazza and J. Rojo, Tuning PYTHIA 8.1: the Monash 2013 Tune, Eur. Phys. J. C 74 (2014) 3024 [arXiv:1404.5630] [INSPIRE].
A.H. Hoang, S. Mantry, A. Pathak and I.W. Stewart, Nonperturbative Corrections to Soft Drop Jet Mass, JHEP 12 (2019) 002 [arXiv:1906.11843] [INSPIRE].
A. Pathak, I.W. Stewart, V. Vaidya and L. Zoppi, EFT for Soft Drop Double Differential Cross Section, JHEP 04 (2021) 032 [arXiv:2012.15568] [INSPIRE].
T. Sjöstrand et al., An introduction to PYTHIA 8.2, Comput. Phys. Commun. 191 (2015) 159 [arXiv:1410.3012] [INSPIRE].
M. Dasgupta, L. Magnea and G.P. Salam, Non-perturbative QCD effects in jets at hadron colliders, JHEP 02 (2008) 055 [arXiv:0712.3014] [INSPIRE].
G.P. Korchemsky and G.F. Sterman, Power corrections to event shapes and factorization, Nucl. Phys. B 555 (1999) 335 [hep-ph/9902341] [INSPIRE].
M. Dasgupta et al., Logarithmic accuracy of parton showers: a fixed-order study, JHEP 09 (2018) 033 [Erratum ibid. 03 (2020) 083] [arXiv:1805.09327] [INSPIRE].
F. Herren et al., A new approach to color-coherent parton evolution, JHEP 10 (2023) 091 [arXiv:2208.06057] [INSPIRE].
S. Höche, D. Reichelt and F. Siegert, Momentum conservation and unitarity in parton showers and NLL resummation, JHEP 01 (2018) 118 [arXiv:1711.03497] [INSPIRE].
S. Höche, F. Krauss and D. Reichelt, The alaric parton shower for hadron colliders, arXiv:2404.14360 [INSPIRE].
L.P. Csernai, Introduction to relativistic heavy ion collisions, Wiley (1994) [INSPIRE].
A. Accardi et al., Hard probes in heavy ion collisions at the LHC: jet physics, hep-ph/0310274 [INSPIRE].
J.D. Bjorken, Energy Loss of Energetic Partons in Quark - Gluon Plasma: possible Extinction of High p(t) Jets in Hadron - Hadron Collisions, FERMILAB-PUB-82-059-THY (1982) [INSPIRE].
M. Gyulassy and M. Plumer, Jet Quenching in Dense Matter, Phys. Lett. B 243 (1990) 432 [INSPIRE].
X.-N. Wang and M. Gyulassy, HIJING: a Monte Carlo model for multiple jet production in p p, p A and A A collisions, Phys. Rev. D 44 (1991) 3501 [INSPIRE].
X.-N. Wang and M. Gyulassy, Gluon shadowing and jet quenching in A + A collisions at \( \sqrt{s} \) = 200-GeV, Phys. Rev. Lett. 68 (1992) 1480 [INSPIRE].
M. Gyulassy and X.-N. Wang, Multiple collisions and induced gluon Bremsstrahlung in QCD, Nucl. Phys. B 420 (1994) 583 [nucl-th/9306003] [INSPIRE].
J. Casalderrey-Solana and C.A. Salgado, Introductory lectures on jet quenching in heavy ion collisions, Acta Phys. Polon. B 38 (2007) 3731 [arXiv:0712.3443] [INSPIRE].
D. d’Enterria, Jet quenching, Landolt-Bornstein 23 (2010) 471 [arXiv:0902.2011] [INSPIRE].
C.A. Salgado and U.A. Wiedemann, Medium modification of jet shapes and jet multiplicities, Phys. Rev. Lett. 93 (2004) 042301 [hep-ph/0310079] [INSPIRE].
N. Borghini and U.A. Wiedemann, Distorting the hump-backed plateau of jets with dense QCD matter, hep-ph/0506218 [INSPIRE].
N. Armesto, L. Cunqueiro and C.A. Salgado, Implementation of a medium-modified parton shower algorithm, Eur. Phys. J. C 61 (2009) 775 [arXiv:0809.4433] [INSPIRE].
N. Armesto, C. Pajares and P. Quiroga-Arias, Medium dependence of multiplicity distributions in MLLA, Eur. Phys. J. C 61 (2009) 779 [arXiv:0809.4428] [INSPIRE].
R. Perez Ramos, Medium-modified average multiplicity and multiplicity fluctuations in jets, Eur. Phys. J. C 62 (2009) 541 [arXiv:0811.2418] [INSPIRE].
R. Perez Ramos, Medium-modified evolution of multiparticle production in jets in heavy-ion collisions, J. Phys. G 36 (2009) 105006 [arXiv:0811.2934] [INSPIRE].
A. Dainese, C. Loizides and G. Paic, Leading-particle suppression in high energy nucleus-nucleus collisions, Eur. Phys. J. C 38 (2005) 461 [hep-ph/0406201] [INSPIRE].
J. Casalderrey-Solana et al., A Hybrid Strong/Weak Coupling Approach to Jet Quenching, JHEP 09 (2014) 175 [Erratum ibid. 09 (2015) 175] [arXiv:1405.3864] [INSPIRE].
T. Luo, Y. He, X.-N. Wang and Y. Zhu, Jet propagation within a Linearized Boltzmann Transport Model, Nucl. Phys. A 932 (2014) 99 [arXiv:1504.03741] [INSPIRE].
B. Schenke, C. Gale and S. Jeon, MARTINI: an event generator for relativistic heavy-ion collisions, Phys. Rev. C 80 (2009) 054913 [arXiv:0909.2037] [INSPIRE].
P. Caucal, E. Iancu, A.H. Mueller and G. Soyez, Vacuum-like jet fragmentation in a dense QCD medium, Phys. Rev. Lett. 120 (2018) 232001 [arXiv:1801.09703] [INSPIRE].
I.P. Lokhtin and A.M. Snigirev, A model of jet quenching in ultrarelativistic heavy ion collisions and high-p(T) hadron spectra at RHIC, Eur. Phys. J. C 45 (2006) 211 [hep-ph/0506189] [INSPIRE].
J.H. Putschke et al., The JETSCAPE framework, arXiv:1903.07706 [INSPIRE].
B. Schenke, S. Jeon and C. Gale, (3+1)D hydrodynamic simulation of relativistic heavy-ion collisions, Phys. Rev. C 82 (2010) 014903 [arXiv:1004.1408] [INSPIRE].
I. Karpenko, P. Huovinen and M. Bleicher, A 3+1 dimensional viscous hydrodynamic code for relativistic heavy ion collisions, Comput. Phys. Commun. 185 (2014) 3016 [arXiv:1312.4160] [INSPIRE].
C. Shen et al., The iEBE-VISHNU code package for relativistic heavy-ion collisions, Comput. Phys. Commun. 199 (2016) 61 [arXiv:1409.8164] [INSPIRE].
D. Bazow, U.W. Heinz and M. Strickland, Massively parallel simulations of relativistic fluid dynamics on graphics processing units with CUDA, Comput. Phys. Commun. 225 (2018) 92 [arXiv:1608.06577] [INSPIRE].
L.-G. Pang, H. Petersen and X.-N. Wang, Pseudorapidity distribution and decorrelation of anisotropic flow within the open-computing-language implementation CLVisc hydrodynamics, Phys. Rev. C 97 (2018) 064918 [arXiv:1802.04449] [INSPIRE].
G. Altarelli and G. Parisi, Asymptotic Freedom in Parton Language, Nucl. Phys. B 126 (1977) 298 [INSPIRE].
R. Baier et al., Radiative energy loss of high-energy quarks and gluons in a finite volume quark - gluon plasma, Nucl. Phys. B 483 (1997) 291 [hep-ph/9607355] [INSPIRE].
R. Baier et al., Radiative energy loss and p(T) broadening of high-energy partons in nuclei, Nucl. Phys. B 484 (1997) 265 [hep-ph/9608322] [INSPIRE].
B.G. Zakharov, Fully quantum treatment of the Landau-Pomeranchuk-Migdal effect in QED and QCD, JETP Lett. 63 (1996) 952 [hep-ph/9607440] [INSPIRE].
B.G. Zakharov, Radiative energy loss of high-energy quarks in finite size nuclear matter and quark - gluon plasma, JETP Lett. 65 (1997) 615 [hep-ph/9704255] [INSPIRE].
B.G. Zakharov, Light cone path integral approach to the Landau-Pomeranchuk-Migdal effect, Phys. Atom. Nucl. 61 (1998) 838 [hep-ph/9807540] [INSPIRE].
U.A. Wiedemann, Jet quenching versus jet enhancement: a quantitative study of the BDMPS-Z gluon radiation spectrum, Nucl. Phys. A 690 (2001) 731 [hep-ph/0008241] [INSPIRE].
U.A. Wiedemann, Gluon radiation off hard quarks in a nuclear environment: opacity expansion, Nucl. Phys. B 588 (2000) 303 [hep-ph/0005129] [INSPIRE].
R. Baier, D. Schiff and B.G. Zakharov, Energy loss in perturbative QCD, Ann. Rev. Nucl. Part. Sci. 50 (2000) 37 [hep-ph/0002198] [INSPIRE].
C.A. Salgado and U.A. Wiedemann, A dynamical scaling law for jet tomography, Phys. Rev. Lett. 89 (2002) 092303 [hep-ph/0204221] [INSPIRE].
M. Gyulassy, I. Vitev, X.-N. Wang and B.-W. Zhang, Jet quenching and radiative energy loss in dense nuclear matter, nucl-th/0302077 [https://doi.org/10.1142/9789812795533_0003] [INSPIRE].
A. Kovner and U.A. Wiedemann, Gluon radiation and parton energy loss, hep-ph/0304151 [https://doi.org/10.1142/9789812795533_0004] [INSPIRE].
C.A. Salgado and U.A. Wiedemann, Calculating quenching weights, Phys. Rev. D 68 (2003) 014008 [hep-ph/0302184] [INSPIRE].
K.C. Zapp, J. Stachel and U.A. Wiedemann, A local Monte Carlo framework for coherent QCD parton energy loss, JHEP 07 (2011) 118 [arXiv:1103.6252] [INSPIRE].
A.D. Polosa and C.A. Salgado, Jet Shapes in Opaque Media, Phys. Rev. C 75 (2007) 041901 [hep-ph/0607295] [INSPIRE].
K.C. Zapp, F. Krauss and U.A. Wiedemann, A perturbative framework for jet quenching, JHEP 03 (2013) 080 [arXiv:1212.1599] [INSPIRE].
K.C. Zapp, Geometrical aspects of jet quenching in JEWEL, Phys. Lett. B 735 (2014) 157 [arXiv:1312.5536] [INSPIRE].
K.C. Zapp, F. Krauss and U.A. Wiedemann, Explaining Jet Quenching with Perturbative QCD Alone, arXiv:1111.6838 [INSPIRE].
L.D. Landau and I. Pomeranchuk, Limits of applicability of the theory of bremsstrahlung electrons and pair production at high-energies, Dokl. Akad. Nauk Ser. Fiz. 92 (1953) 535 [INSPIRE].
A.B. Migdal, Bremsstrahlung and pair production in condensed media at high-energies, Phys. Rev. 103 (1956) 1811 [INSPIRE].
K. Zapp, J. Stachel and U.A. Wiedemann, A Local Monte Carlo implementation of the non-abelian Landau-Pomerantschuk-Migdal effect, Phys. Rev. Lett. 103 (2009) 152302 [arXiv:0812.3888] [INSPIRE].
K. Zapp, G. Ingelman, J. Rathsman and J. Stachel, Jet quenching from soft QCD scattering in the quark-gluon plasma, Phys. Lett. B 637 (2006) 179 [hep-ph/0512300] [INSPIRE].
J.D. Bjorken, Highly Relativistic Nucleus-Nucleus Collisions: the Central Rapidity Region, Phys. Rev. D 27 (1983) 140 [INSPIRE].
K.J. Eskola, K. Kajantie and J. Lindfors, Quark and Gluon Production in High-Energy Nucleus-Nucleus Collisions, Nucl. Phys. B 323 (1989) 37 [INSPIRE].
ATLAS collaboration, ATLAS Monte Carlo tunes for MC09, ATL-PHYS-PUB-2010-002 (2010) [INSPIRE].
CTEQ collaboration, Global QCD analysis of parton structure of the nucleon: CTEQ5 parton distributions, Eur. Phys. J. C 12 (2000) 375 [hep-ph/9903282] [INSPIRE].
S. Dulat et al., New parton distribution functions from a global analysis of quantum chromodynamics, Phys. Rev. D 93 (2016) 033006 [arXiv:1506.07443] [INSPIRE].
M. van Leeuwen, Jet Fragmentation and Jet Shapes in JEWEL and Q-PYTHIA, in the proceedings of the 7th International Conference on Hard and Electromagnetic Probes of High-Energy Nuclear Collisions, Montréal, Canada, June 29 – July 03 (2015) [https://doi.org/10.1016/j.nuclphysbps.2016.05.067] [arXiv:1511.06108] [INSPIRE].
I.M. Dremin, G.K. Eyyubova, V.L. Korotkikh and L.I. Sarycheva, Two-dimensional discrete wavelet analysis of multiparticle event topology in heavy ion collisions, Indian J. Phys. 85 (2011) 39 [arXiv:0711.1657] [INSPIRE].
J.G. Milhano and K. Zapp, Improved background subtraction and a fresh look at jet sub-structure in JEWEL, Eur. Phys. J. C 82 (2022) 1010 [arXiv:2207.14814] [INSPIRE].
B. Yan and C. Lee, Probing light quark Yukawa couplings through angularity distributions in Higgs boson decay, JHEP 03 (2024) 123 [arXiv:2311.12556] [INSPIRE].
A. Ferdinand, K. Lee and A. Pathak, Field-theoretic analysis of hadronization using soft drop jet mass, Phys. Rev. D 108 (2023) L111501 [arXiv:2301.03605] [INSPIRE].
Acknowledgments
SS acknowledges support from BMBF (05H21MGCAB) and from Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) — project number 456104544. The work of DR was supported by the STFC IPPP grant (ST/T001011/1). The work of OF and YTC is supported in part by the US Department of Energy (DOE) Contract No. DE-AC05-06OR23177, under which Jefferson Science Associates, LLC operates Jefferson Lab, and by the Department of Energy Early Career Award grant DE-SC0023304. We are grateful to Liliana Apolinário and Néstor Armesto for providing the version of the Q-Pythia code specifically tuned for the RHIC setup. We also would like to thank Roli Esha and Megan Connors for useful and fruitful discussions on the potential of the sPHENIX experiment for jet angularity measurements. Most of the simulation is conducted with computing facilities of the Galileo cluster at the Department of Physics and Astronomy of Georgia State University.
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Chien, YT., Fedkevych, O., Reichelt, D. et al. Jet angularities in dijet production in proton-proton and heavy-ion collisions at RHIC. J. High Energ. Phys. 2024, 230 (2024). https://doi.org/10.1007/JHEP07(2024)230
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DOI: https://doi.org/10.1007/JHEP07(2024)230