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Calculating Higher Order Corrections: An Update

Calculating Higher Order Corrections: An Update. Lance Dixon ALCPG04 Theorist’s Rally for the LC SLAC, 1/7/04. Outline. NLO (EW+QCD) corrections to Higgs production NNLO QCD corrections to event shapes (prospects). NLO corrections to Higgs production.

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Calculating Higher Order Corrections: An Update

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  1. Calculating Higher Order Corrections: An Update Lance Dixon ALCPG04 Theorist’s Rally for the LC SLAC, 1/7/04

  2. Outline • NLO (EW+QCD) corrections to Higgs production • NNLO QCD corrections to event shapes (prospects)

  3. NLO corrections to Higgs production • Important for extracting Higgs couplings • Electroweak corrections at 500 GeV can be ~ 10% • Processes Considered: Higgstrahlung: gHZZ WW fusion: gHWW Top-associated production: gHtt

  4. NLO ZH and nnH production One-loop corrections are all electroweak. • nnH process is particularly • challenging due to: • large number of virtual diagrams • (1350 in all; “only” 249 lacking le) • complicated 5-point integrals • (98 in all; “only” 15 lacking le) First nnH calculation used GRACE-LOOP to generate, evaluate loop diagrams; nonlinear gauge for diagram checking. Belanger et al., hep-ph/0212261 Second independent calculation: Denner et al., hep-ph/0301189

  5. NLO ZH and nnH production results Denner et al., hep-ph/0301189 Belanger et al., hep-ph/0211268, hep-ph/0212261 IBA scheme (?): set a to a(MZ); similarly for g2(MW) “Blips” due to 2-particle intermediate state rescatterings (WW, ZZ, tt). Largest corrections to IBA are near end of phase space, where Born cross section varies rapidly (and is tiny anyway).

  6. ZH experimental accuracy Conclusion: Theoretical corrections to s(e+e- -> ZH) are under good control; they only get large (vs. IBA) where experimental accuracy suffers. Is the same true of WW fusion process? Probably, at least at 500 GeV… hep-ph/0311092

  7. - NLO ttH production Now there are QCD and electroweak corrections. QCD corrections were computed first. “Standard” NLO QCD formalism, but also IR divergent 5-point integrals. They are modest away from threshold. Dawson, Reina, hep-ph/9808443 Dittmaier et al., hep-ph/9808433 Electroweak corrections turn out to be comparable You et al., hep-ph/0306036 Belanger et al., hep-ph/0307029 Denner et al., hep-ph/0307193, hep-ph/0309274 (latter two agree well)

  8. - ttH experimental accuracy hep-ph/0311092 Conclusion: Theoretical corrections to s(e+e- -> ttH) are also now under good control: 10-20% NLO corrections are ~ experimental uncertainty in g2ttH

  9. Prospects for NNLO corrections to e+e- event shapes • Important for extracting a preciseas at large momentum transferQ • Many fewer hadronic events than at the Z resonance • Also more backgrounds • However, nonperturbative corrections~1/Q

  10. Motivation • e+e- annihilation to hadrons is experimentallyclean • Atfull energy LC, notquiteas clean as atMZ: • UseeR-to suppressWWbackground • Useanti-b-tagging to suppressttbackground (Schumm, hep-ex/9612013; Schumm, Truitt, hep-ex/0102010; Burrows, hep-ex/0112036) • Excellent opportunity forhigh Q2, cleanas(Q)measurement • as(MZ)is biggestuncertainty now in testing GUT coupling constant unification. • as(MZ)an important input into other LC physics; e.g. extraction ofmtfromttthreshold scan. • With Giga-Z (or LEP/SLCarchival data), compare full energy results toMZresults to fit out nonperturbative (1/Q) corrections

  11. Need for NNLO • Measurements ofas in 3-jet rate, other e+e- event shapes, dominated bytheoretical uncertainty due mainly to truncation of perturbative series atNLO: • Fit toNLOtheory leads to: large scatterinas values from different event shapes, large renormalization scale dependence Burrows, hep-ex/9709010

  12. What about NLO EW corrections? • Sudakov effects lead to growth withQ: • Result for Thrust distribution at 1 TeV: Maina et al., hep-ph/0210015 • However, it depends on how result isnormalized;normalizing tosinstead ofs0 will givemuch smallerEW corrections, except atvery large 1-T. • True momentum scale is~(1-T)2Q.

  13. NNLO QCD Diagram Types

  14. Status of NNLO Diagrams (Amplitudes)

  15. Remaining Obstacle: Phase-space integration • 3 types of terms, each contributes1/e4 + … singularities using dimensional regularization,D=4-2e, for all integrals. • 5 partons, tree x tree • 4 partons, 1-loop x tree • 3 partons, 2-loop x tree and 1-loop x 1-loop • 3-partonphase-space integrationstrivial(all partons visible) • 5-partons(doubly unresolved) thehardest. Several types of singular regions, behavior ofsunderstood: • double soft Berends, Giele (1989) • 2 collinear + 1 soft Campbell, Glover, hep-ph/9710255 • 3 collinear Catani, Grazzini, hep-ph/9810389, 9908523 • 2 collinear, twice Del Duca, Frizzo, Maltoni, hep-ph/9909464 • plus overlaps

  16. Recent Advances in Phase-space integration • Analytic behavior of5-partoncross section inindividual singular regions understood for a while; more recently formulasinterpolatingbetween the different regions have been found: • Kosower, hep-ph/0301069; Weinzierl, hep-ph/0302180, 0306248. • If such formulae were simple enough to integrate analytically, they could besubtractedfrom the exact integrand, and the finitedifference integrated numerically over phase-space in 4-dimensions. • However, this has not yet been done.

  17. Recent Advances (cont.) • More recently, the technique ofsector decomposition, Binoth, Heinrich, hep-ph/0004013 originally developed for loop integrals, has been applied todoubly unresolved phase-space integrals: • Gehrmann-De Ridder et al., hep-ph/0311276 • Anastasiou et al., hep-ph/0311311 • Anastasiou et al. have been able to compute integrals for theNNLOe+e- -> 2-jetratein this way.

  18. Sector decomposition • One-dimensional singular integrals are easily expanded in eusing “plus” distributions: where • To expand a multi-dimensional singular integral such as first split intosectors:x > y x < y

  19. Sector decomposition (cont.) • Let y = y’xin I1x = x’yinI2 • Now that the singularities are separated, expansion inecan be carried out as in 1-dimensional case. • Anastasiou et al. found a parametrization of 4-parton phase space (5 variables) which is amenable to automated sector decomposition:

  20. Sector decomposition (cont.) • As an example, they numerically integrated the 4-parton contribution to the Nf-dependent part of the NNLO 2-jet rate(JADE algorithm, y=0.1) order-by-order in e: • Adding the (2,3)-parton contributions, the 1/e poles cancel, and the right answer is obtained (s2+s3+s4 = stot is known)

  21. Sector decomposition (cont.) • Most important lessons of this technique: • It is not necessary (for a human) to understand the behavior of the integrand in the various singular regions. • It is not necessary to integrate singular terms analytically to verify cancellations. • Method looks generalizable to the NNLO3-jet problem • Either by a direct attack on the 5-particle phase space (5-variables -> 8-variables) • Or by using it to integrate subtraction terms over 4-particle subspaces.

  22. Conclusions • Much recent progress in computing NLO QCD and particularly electroweak corrections for important multi-body final-state electroweak processes at a linear collider. • Here, surveyed a few relevant for precision extraction of Higgs couplings. With the one-loop EW corrections, theoretical precision generally appears adequate. • For precision measurement of as, NNLOQCD corrections to hadronic event shapes are required, but not yet available. However, I predict they will be within a year, due to recent progress and the upcoming KITP workshop in collider physics.

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