Associated Top-Pair Production with a Heavy Boson at the LHC

1. Associated Top-pair Production with a heavy boson through NNLL+NLO accuracy at the LHC Anna Kulesza University of Münster In collaboration with L. Motyka, D. Schwartländer, T. Stebel and V. Theeuwes • Rencontres de Moriond QCD & High Energy Interactions 23-30 March 2019

2. Ttbar+Heavy Boson production A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

3. Associated Higgs Production with Top Quarks • Direct probe of the strength of the top-Yukawa coupling • An example of a 2⟶3 process for which full NNLO results are not available yet • Crucial for understanding the Higgs sector and in searches for deviations from the SM • Far-reaching consequences → stability of our Universe ATLAS, Run1 + Run2: 6.3σ (5.1σ exp.) CMS, Run1 + Run2: 5.2σ (4.9σ exp.) [Buttazzo et al.’13] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

4. TTbar+W,Z • Probes of top-quark couplings • Sensitive to BSM contributions • Dominant backgrounds to searches and SM precision measurements (ttH included) • Signal strength (CMS): ttW ttZ CMS, 1711.02547 ATLAS, 1609.01599 A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

5. Theory Status for TTbarH Fixed order perturbation theory • NLO QCD available since (almost) 20 years [Beenakker, Dittmaier, Krämer, Plumper, Spira, Zerwas ’01-’02][Reina, Dawson’01][Reina, Dawson, Wackeroth’02][Dawson,Orr,Reina,Wackeroth’03] [Dawson, Jackson, Orr, Reina, Wackeroth’03] • NLO QCD matched with parton showers • POWHEG-Box [Garzelli, Kardos,Papadopoulos,Trocsanyi’11] [Hartanto, Jäger,Reina, Wackeroth’15] • aMC@NLO[Frederix, Frixione, Hirschi, Maltoni, Pittau, Torrielli’11] • SHERPA+RECOLA [Biedermann et al.’17] • QCD and EW@NLO [Frixione, Hirschi, Pagani,Shao,Zaro’14-’15][Zhang, Ma, Zhang, Chen, Guo’14][Biedermann, Bräuer, Denner, Pellen, Schumann, Thompson’17] • NLO QCD [Denner, Feger’15] and EW [Denner,Lang, Pellen, Uccirati’16] with tops off-shell • Top decays into b quarks and leptons: pp➝ ttH ➝ W+W-bbH➝e+νeμ-νμbb H • All resonant, non-resonant, interference and off-shell effects included - A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

6. Theory Status For TTbar+W,Z Fixed order perturbation theory • NLO QCD [Lazopoulos, Melnikov, Petriello’07] [Lazopoulos, McElmurry, Melnikov, Petriello’08] [Kardos, Trocsanyi, Papadopoulos’12 ] withdecays at NLO [Campbell, Ellis’12][Roentsch, Schulze’14-’15] • NLO interfaced to parton showers inaMC@NLO[Alwall, Frederix, Frixione, Hirschi, Maltoni, Mattalaer, Shao Stelzer, Torrieli, Zaro,’14] [Maltoni, Mangano, Tsinikos, Zaro,’14] [Maltoni, Pagani, Tsinikos’15]and POWHEG-Box [Garzelli, Kardos,Papadopoulos,Trocsanyi’12] • NLO EW (+QCD) corrections [Frixione, Hirschi, Pagani,Shao,Zaro’14-15][Frederix, Pagani, Zaro’18] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

7. Why Resummation? • Extending accuracy of the perturbative prediction beyond fixed-order by adding a systematic treatment of logarithmic contributions due to soft gluon emission is a common standard in precision phenomenology • better description of physics: additional corrections to cross sections… especially interesting when NNLO calculations out of reach • improvement or, in some cases, restoration of predictive power of perturbation theory • reduction of the theory error due to scale variation sums up LL: αsn log n+1 (N) NLL: αsn log n (N) NNLL: αsn log n-1 (N) Factorization at threshold: space of Mellin moments N, taken wrt. M2/S (absolute threshold) or Q2/S (invariant mass threshold) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

8. Beyond NLO QCD: Resummation 2 • ttH: NLL+NLO resummation in the absolute threshold limit, obtained using direct QCD approach • ttH: “Approximated” NNLO based on the SCET approach to resummation in the invariant mass limit • ttH: NLL+NLO in the invariant mass limit for production with pseudoscalar Yukawa couplings • ttW: NNLL+NLO resummation in the invariant mass limit, SCET [Li, Li, Li’14] • ttH, ttW, ttZ: NNLL+NLO resummation in the invariant mass limit, hybrid SCET/direct QCD method[Broggio, Ferroglia, Ossola, Pecjak’16] [Broggio, Ferroglia, Pecjak, Yang’16][Broggio, Ferroglia, Ossola, Pecjak, Samoshima’17] • ttH, ttW, ttZ: NNLL+NLO resummation in the invariant mass limit, direct QCD method [AK, Motyka, Stebel, Theeuwes’16], [AK, Motyka, Stebel, Theeuwes’17], [AK, Motyka, Schwartländer, Stebel, Theeuwes’18] [AK, Motyka, Stebel, Theeuwes’15] [Broggio, Ferroglia, Pecjak, Signer, Yang’15] [Broggio, Ferroglia, Fiolhais, Onofre’17] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

9. Resummation forTTbar+B • Thresholdlimit in thetriple invariant masskinematics: • Direct QCD → Nspace: • Factorization ⟷ resummation Hard off-shell Collinear Soft wide-angle ✓ Universal, known Process-dependent Hard and soft functions are now matrices in colour space A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

10. NNLL forTtbar+B = • Soft functionfromthesolutionofthe RG equation • Soft anomalous dimensions known at two loops for any number of legs [Mert-Aybat, Dixon, Sterman’06] [Becher, Neubert’09][Mitov, Sterman, Sung’09-’10] [Ferroglia, Neubert, Pecjak, Yang’09] [Beneke, Falgari, Schwinn’09], [Czakon, Mitov, Sterman’09] [Kidonakis’10]✓ • Tocalculate, eliminatepath-orderedexponentials: • usebasisthatdiagonalize→ enoughfor NLL accuracy • For NNLL, treatmatricesU perturbatively[Buras‘80][Buchalla, Buras, Lautenbacher’96] ] [Ahrens, Ferroglia, Neubert, Pecjak, Yang’10] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

11. NNLL forTtbar+B = • Soft functionfromthesolutionofthe RGE equation • Soft anomalous dimensions known at two loops for any number of legs [Mert-Aybat, Dixon, Sterman’06] [Becher, Neubert’09][Mitov, Sterman, Sung’09-’10] [Ferroglia, Neubert, Pecjak, Yang’09] [Beneke, Falgari, Schwinn’09], [Czakon, Mitov, Sterman’09] [Kidonakis’10]✓ • Tocalculate, eliminatepath-orderedexponentials: • usebasisthatdiagonalize→ enoughfor NLL accuracy • For NNLL, treatmatricesU perturbatively[Buras‘80][Buchalla, Buras, Lautenbacher’96] ] [Ahrens, Ferroglia, Neubert, Pecjak, Yang’10] • Hard function • H(1)extracted from aMC@NLO[Frederix, Frixione, Hirschi, Maltoni, Pittau, Torrielli’11] (ttH, ttW, ttZ) andPowHel (HELAC-NLO [Bevilacqua et al.’11] +POWHEG-Box) package [Garzelli, Kardos, Papadopoulos,Trocksanyi’11] (ttH) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

12. Invariant Mass Distribution for TTbarH [AK, Motyka, Stebel, Theeuwes’17] • NNLL+NLO distributions for the two considered scale choices very close, NLO results differ visibly → KNNLL = 𝜎NLO+NNLL / 𝜎NLOfactors also different • NNLL+NLO error band slightly narrower than NLO (7-point method) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

13. Invariant Mass Distribution for TTbarH [AK, Motyka, Stebel, Theeuwes’17] • NNLL+NLO distributions for the two considered scale choices very close, NLO results differ visibly → KNNLL = 𝜎NLO+NNLL / 𝜎NLO factors also different • NNLL+NLO error band slightly narrower than NLO (7-point method) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

14. Total Cross Section for TTbarH [AK, Motyka, Stebel, Theeuwes’17] KNNLL= 𝜎NLO+NNLL / 𝜎NLO A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

15. Total Cross Section for TTbarH [AK, Motyka, Stebel, Theeuwes’17] • Compared to NLO, remarkable stability of NLO+NNLL • Stability improves with increasing accuracy of resummation • Reduction of the theory scale error • “Best” NNLL+NLO prediction in agreement with NLO at μ0 = M/2 A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

16. Total Cross Section for TTbar+W,Z [AK, Motyka, Schwartläder, Stebel, Theeuwes’18] • Significant reduction in the scale dependence of the ttZ total cross section • Comparison with SCET results, wherever possible [Li et al.’14], [Broggio et al.’16-’17] ✓ A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

17. Ttbar+W,Z at NLO+NNLL [AK, Motyka, Schwartländer, Stebel, Theeuwes’18] • State of the art: QCD NLO+NNLL, combined with (additively) NLO EW [Frixione et al. ’14-15] • Central values of the theoretical predictions brought closer to the measured cross section; theory errors reduced (by half for ttZ) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

18. Summary • ttH production @ the LHC is one of the most promising windows onto new physics • ttW and ttZ also very important for BSM searches as well as tests of the SM Precise theoretical prediction are essential ➝ a lot of recent progress! • Resummed calculations for reach NNLL+NLO accuracy -- first application of resummation to the class of 2->3 processes • Remarkable stability of the NNLL+NLO differential and total cross sections w.r.t. scale variation; improving stability with growing accuracy • Reduction of the theory error due to scale variation A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

19. BACKUP A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

20. Invariant Mass Kinematics Problem: hard and soft functions are now (and in general) matrices in colour space Diagonalization procedure leads to, at NLL: [Kidonakis, Oderda, Sterman’98] where λ’s are eigenvalues of the one-loop soft-anomalous dimension matrix A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

21. Invariant Mass Kinematics Problem: hard and soft functions are now (and in general) matrices in colour space Diagonalization procedure leads to, at NLL: [Kidonakis, Oderda, Sterman’98] where λ’s are eigenvalues of the one-loop soft-anomalous dimension matrix A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

22. Invariant Mass Kinematics Ctnd. • Extending resummation in this kinematics to NNLL requires: • Knowledge of the two-loop soft anomalous dimension • Amended treatment of the path-ordered exponential to account for it • Knowledge of the one-loop hard-matching coefficient A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

23. Invariant Mass Kinematics Ctnd. • Extending resummation in this kinematics to NNLL requires: • Knowledge of the two-loop soft anomalous dimension ✔Soft anomalous dimensions known at two loops for any number of legs[Mert-Aybat, Dixon, Sterman’06] [Becher, Neubert’09][Mitov, Sterman, Sung’09-’10] [Ferroglia, Neubert, Pecjak, Yang’09] [Beneke, Falgari, Schwinn’09], [Czakon, Mitov, Sterman’09] [Kidonakis’10] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

24. Invariant Mass Kinematics Ctnd. • Extending resummation in this kinematics to NNLL requires: • Knowledge of the two-loop soft anomalous dimension • Amended treatment of the path-ordered exponential to account for it ✔Perturbative expansion [Buchalla, Buras, Lautenbacher’96] [Ahrens, Neubert, Pecjak, Yang’10] eigenvalues of Γ(1) A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

25. Invariant Mass Kinematics Ctnd. • Extending resummation in this kinematics to NNLL requires: • Knowledge of the two-loop soft anomalous dimension • Amended treatment of the path-ordered exponential to account for it • Knowledge of the one-loop hard function HIJ • needs access to colour structure of virtual corrections • ✔extracted from the results provided by the PowHel (HELAC-NLO [Bevilacqua et al.’11] +POWHEG-Box) package [Garzelli, Kardos, Papadopoulos,Trocksanyi’11] • translation between the colour flow and singlet-octet basis • implementation checked against colour-averaged virtual corrections obtained from public POWHEG [Hartanto, Jäger,Reina,Wackeroth’15] and aMC@NLO implementations [Frederix, Frixione, Hirschi, Maltoni, Pittau, Torrielli’11] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

26. Scale dependence of the total cross section [AK, Motyka, Stebel, Theeuwes’17] μF = μ0 = Q μR = μ0 = Q • Apparent cancellations between μFand μRscale dependence • No significant change in dependence on μRwhile increasing the accuracy: αs running effect • μFdependence modified by the hard-matching coefficient 7-point method A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

27. Absolute Threshold Resummation for QQB @NLO+NLL Colour space basis in which ΓIJ is diagonal in the threshold limit incoming jet factors, known soft-wide angle emission hard function Hab →kl B,I At NLL accuracy Cab →kl B,I = 1 A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

28. One-Loop Soft Anomalous Dimension singlet-octet colour basis Reduces to the 2->2 case in the limit pB→0, mB→0 Absolute threshold limit: non-diagonal terms vanish Coefficients D(1)ab →kl B,I governing soft emission same as for the QQbar process: soft emission at absolute threshold driven only by the color structure A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

29. The Case of Associated Heavy Boson-Heavy quark Pair Production • Absolute threshold limit but: • LO cross section suppressed in the limit β→0 as β4 due to massive 3-particle phase-space • Absolute threshold scale M away from the region contributing the most nevertheless: • Well defined class of corrections which can be resummed [AK, Motyka, Stebel, Theeuwes’15] - PDF4LHC15_100 pdfs, NLO from aMC@NLO [Alwall, Frederix, Frixione, Hirschi, Maltoni, Mattelaer, Shao, Stelzer, Torrielli, Zaro] A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

30. Associated Higgs Production with Top Quarks, Resummation in the absolute threshold limit [ AK, Motyka, Stebel, Theeuwes’15] • Shows also a strong impact of the hard-matching coefficient C on the predictions → contributions away from the absolute threshold matter! • Part of these contributions can be accounted for if instead of resummation for total cross section, resummation for invariant mass of the ttbarH system is considered A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC

31. Associated Higgs Production with Top Quarks, Resummation in the absolute threshold limit AK, Motyka, Stebel, Theeuwes’15] • Threshold logarithms under scrutiny: • NLL accuracy requires knowledge of NLO soft anomalous dimension with 2⟶3 kinematics and NLO cross section at threshold split into colour channels MMHT2014NLO NLO obtained with aMC@NLO A. Kulesza, Associated top-pair & heavy boson production through NNLL+NLO accuracy at the LHC