Factorization for groomed jet substructure beyond the next-to-leading logarithm

Abstract: Jet grooming algorithms are widely used in experimental analyses at hadron colliders to remove contaminating radiation from within jets. While the algorithms perform a great service to the experiments, their intricate algorithmic structure and multiple parameters has frustrated precision theoretic understanding. In this paper, we demonstrate that one particular groomer called soft drop actually makes precision jet substructure easier. In particular, we derive a factorization formula for a large class of soft d… Show more

“…[8,12]. Analytical calculations have also been performed for the SoftDrop method [13][14][15] and for radiation constraining jet shapes [16,17] based on the N-subjettiness class of variables [18] and energy correlation functions (ECFs) [19]. These calculations have enabled a much more detailed and robust understanding of jet substructure methods than was possible with purely numerical studies from Monte Carlo event generators.…”

“…(2.8) can be written in the form 1 σ dσ dρ 14) where the first term on the r.h.s. contains the leading logarithms in ρ while the second term is subleading in ρ (being purely single logarithmic), although it is enhanced by logarithmic terms in y.…”

“…Furthermore, (4.8) is also largely unaffected by a possible mMDT or trimming one would apply after the Y m -splitter condition since the latter guarantees that the emission that dominates the mass carries a momentum fraction larger than y cut . 14 Compared to the pure Y-splitter case, eq. (2.16), we should expect the pre-groomed result (4.8) to show a worse performance.…”

“…Between Y-splitter and Y m -splitter conditions, we have limited ourselves to the latter, since it has a slightly better performance than the former. 15 We have considered both a y cut and a z cut type of JHEP12 (2016) condition, using in practice y cut = z cut = 0.1. We have then studied 4 grooming options: the ungroomed (or pure) case which acts as a baseline, mMDT and trimming both applied after the Y m -splitter condition, and SoftDrop pre-grooming for which the Y m -splitter condition is applied after the pre-grooming.…”

Improved jet substructure methods: Y-splitter and variants with grooming

“…[8,12]. Analytical calculations have also been performed for the SoftDrop method [13][14][15] and for radiation constraining jet shapes [16,17] based on the N-subjettiness class of variables [18] and energy correlation functions (ECFs) [19]. These calculations have enabled a much more detailed and robust understanding of jet substructure methods than was possible with purely numerical studies from Monte Carlo event generators.…”

“…(2.8) can be written in the form 1 σ dσ dρ 14) where the first term on the r.h.s. contains the leading logarithms in ρ while the second term is subleading in ρ (being purely single logarithmic), although it is enhanced by logarithmic terms in y.…”

“…Furthermore, (4.8) is also largely unaffected by a possible mMDT or trimming one would apply after the Y m -splitter condition since the latter guarantees that the emission that dominates the mass carries a momentum fraction larger than y cut . 14 Compared to the pure Y-splitter case, eq. (2.16), we should expect the pre-groomed result (4.8) to show a worse performance.…”

“…Between Y-splitter and Y m -splitter conditions, we have limited ourselves to the latter, since it has a slightly better performance than the former. 15 We have considered both a y cut and a z cut type of JHEP12 (2016) condition, using in practice y cut = z cut = 0.1. We have then studied 4 grooming options: the ungroomed (or pure) case which acts as a baseline, mMDT and trimming both applied after the Y m -splitter condition, and SoftDrop pre-grooming for which the Y m -splitter condition is applied after the pre-grooming.…”

Improved jet substructure methods: Y-splitter and variants with grooming

“…However, in all these measurements the treatment of the background originating from the copiously produced particles not associated to hard scatterings poses an experimental challenge for precise and unbiased measurements. Previous works that addressed the effect of filtering a e-mail: liliana@lip.pt b e-mail: guilherme.milhano@ist.utl.pt c e-mail: mploskon@lbl.gov d e-mail: xiaoming.zhang@cern.ch on subjet analysis [26] and the recent analytic calculations of the momentum distributions of subjets [27][28][29] and groomed jet mass distributions [30][31][32] that were recently measured in proton-proton collisions [33,34], provide a strong motivation for novel studies. In this writeup, following previous works [35], we propose observables that are sensitive to the internal jet structure but significantly alleviate the difficulties associated to the effects of the background.…”

Novel subjet observables for jet quenching in heavy-ion collisions

Top-quark loop corrections in Z+jet and Z + 2 jet production