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Complete QCD Amplitudes: Part II of QCD On-Shell Recursion Relations

Complete QCD Amplitudes: Part II of QCD On-Shell Recursion Relations. with C. Berger, Z. Bern, L. Dixon, D. Forde From Twistors to Amplitudes , Queen Mary, November 3–5, 2005. LHC Is Coming, LHC Is Coming!. Only 600 days to go!. Precision Perturbative QCD.  Del Duca’s talk.

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Complete QCD Amplitudes: Part II of QCD On-Shell Recursion Relations

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  1. Complete QCD Amplitudes: Part II of QCD On-Shell Recursion Relations with C. Berger, Z. Bern, L. Dixon, D. Forde From Twistors to Amplitudes,Queen Mary, November 3–5, 2005

  2. LHC Is Coming, LHC Is Coming! Only 600 days to go!

  3. Precision Perturbative QCD  Del Duca’s talk • Predictions of signals, signals+jets • Predictions of backgrounds • Measurement of luminosity • Measurement of fundamental parameters (s, mt) • Measurement of electroweak parameters • Extraction of parton distributions — ingredients in any theoretical prediction Everything at a hadron collider involves QCD

  4. NLO Jet Physics • Ingredients for n-jet computations • 2 → (n+1) tree-level amplitudes • 2 → n one-loop amplitudes Bern, Dixon, DAK, Weinzierl (1993–8); Kunszt, Signer, Trocsanyi (1994); Campbell, Glover, Miller (1997) • Singular (soft & collinear) behavior of tree-level amplitudes • & their integrals over phase space • Initial-state singular behavior • Incorporated into general numerical programs • Mature technology Giele, Glover, DAK (1993); Frixione, Kunszt, Signer (1995); Catani, Seymour (1996) known since the ’80s only n=3 or W+2 (known for 10 years) known for ~ 10 years known for ~ 10 years Barrier broken!

  5. N =4 = pure QCD + 4 fermions + 3 complex scalars QCD = N =4 + δN = 1 + δN = 0 chiral multiplet scalar cuts + rational cuts + rational cuts + rational D=4−2εunitarity D=4 unitarity D=4 unitarity D=4 unitarity bootstrap or on-shell recursion relations

  6. On-shell Recursion Relations Iteration Relation New Structures in Gauge Theory Complete Loop Calculations in QCD Twistor-String Duality Unitarity-Based Method Higher-LoopIntegral Technology

  7. Three-Vertices • On-shell with real momenta this vanishes • For real momenta, , so all spinor products vanish too • For complex momenta  or but not necessarily both! Witten (2003)

  8. Unitarity-Based Method • Use a general property of amplitudes as a practical tool for computing them • Sew loop amplitudes out of on-shell tree amplitudes: summation of Cutkosky relation • Use knowledge of possible Feynman integrals (field theory origin) & all modern techniques: identities, modern reduction techniques, differential equations, reduction to master integrals, etc. • Can sew more than two tree amplitudes: generalized unitarity

  9. Unitarity-Based Calculations Bern, Dixon, Dunbar, & DAK (1994) • At one loop in D=4 for SUSY  full answer • For non-SUSY theory, must work in D=4-2Є  full answer van Neerven (1986): dispersion relations converge • Merge channels rather than blindly summing: find function w/given cuts in all channels

  10. Generalized Cuts • Isolate contributions of smaller set of integrals, at higher loops as well

  11. Cuts in Massless Channels • With complex momenta, can form cuts using three-vertices too Britto, Cachazo, & Feng (2004)  all box coefficients can be computed directly and algebraically, with no reduction or integration • N =1 and non-supersymmetric theories need triangles and bubbles, for which integration is still needed

  12. Loop Calculations — Integral Basis • Boxes, triangles and bubbles are a basis at one loop

  13. Rational Terms • Implicitly, we’re performing a dispersion integral • in which so long as when • If this condition isn’t satisfied, there are ‘subtraction’ ambiguities corresponding to terms in the full amplitude which have no discontinuities: rational terms • In SUSY theories, or in D=4-2ε, UV convergence is improved so there are no ambiguities

  14. Factorization • Also a general property of field-theory amplitudes • Constrain terms to have correct collinear limit: factorization as a calculational tool • Used in to obtain simple form for rational terms Bern, Dixon, DAK (1997) • Can this be made systematic?

  15. Recursion Relations Berends & Giele (1988); DAK (1989)  Polynomial complexity per helicity

  16. New Representations of Tree Amplitudes • Divergent terms in one-loop NMHV amplitude must be proportional to tree — but the representation found in explicit calculations is simpler than previously-known ones Bern, Del Duca, Dixon, & DAK (2004) • Presence of spurious singularities in individual terms seems indispensable • Suggested new kind of recursion relation Roiban, Spradlin, & Volovich (2004) • On-shell recursion relation Britto, Cachazo, & Feng (2004) • Simple and general proof Britto, Cachazo, Feng, & Witten (1/2005) • ‘Connected-instanton’ representation Roiban, Spradlin, & Volovich (2004)

  17. On-Shell Recursion Relations Britto, Cachazo, Feng (2004); & Witten (1/2005) • Amplitudes written as sum over ‘factorizations’ into on-shell amplitudes — but evaluated for complex momenta

  18. Very general: relies only on complex analysis + factorization • Applied to gravity Bedford, Brandhuber, Spence, & Travaglini (2/2005) Cachazo & Svrček (2/2005) • Massive amplitudes  Glover’s talk Badger, Glover, Khoze, Svrček (4/2005, 7/2005) Forde & DAK (7/2005) • Integral coefficients  Bjerrum-Bohr’s talk Bern, Bjerrum-Bohr, Dunbar, & Ita(7/2005) • Connection to Cachazo–Svrček–Witten construction Risager (8/2005) • CSW construction for gravity  Twistor string for N =8? Bjerrum-Bohr, Dunbar, Ita, Perkins, & Risager (9/2005)

  19. On-Shell Recursion at Loop Level Less is more. My architecture is almost nothing — Mies van der Rohe Bern, Dixon, DAK (1–7/2005) • Complex shift of momenta • Behavior as z : require A(z)  0 • Basic complex analysis: treat branch cuts • Knowledge of complex factorization: • at tree level, tracks known factorization for real momenta • at loop level, there are subtleties  Dixon’s talk • Obtain simpler forms for known finite amplitudes, involving spurious singularities

  20. Rational Parts of QCD Amplitudes • Start with cut-containing parts obtained from unitarity method, consider same contour integral

  21. Derivation • Consider the contour integral • Determine A(0) in terms of other poles and branch cuts • Cut terms have spurious singularities  rational terms do too Cut terms Rational terms

  22. Absorb spurious singularities in rational terms into‘completed-cut’  no sum over residues of spurious poles • entirely known from four-dimensional unitarity method • Assume as • Modified separation • Perform integral & residue sum for

  23. Loop Factorization • Proven structure for real momenta, still experimental for complex momenta • Cut terms → cut terms • Rational terms → rational terms • Build up the latter using recursion, analogous to tree level

  24. Recursion gives • Subtract it off Double-counted: ‘overlap’ Compute explicitly from known Ĉ

  25. Sometimes, as • If , can either subtract from to define a new or simply subtract it from result • Needed for computation ofand when starting from the cuts computed by Bedford, Brandhuber, Spence, & Travaglini (2004)

  26. Five-Point Example • Look at • Recursive diagrams shift • (a) Tree vertex vanishes • (b) Loop vertex vanishes • (c) Loop vertex vanishes • (d) Tree vertex vanishes • (e) Loop vertex vanishes

  27. Five-Point Example (cont.) • ‘Overlap’ contributions

  28. A 2→4 QCD Amplitude Bern, Dixon, Dunbar, & DAK (1994) Only rational terms missing

  29. A 2→4 QCD Amplitude Rational terms

  30. Unwinding • Can we do all-n? Use shift • Apply technique from all-n massive scalar calculation

  31. All-Multiplicity Amplitude • Same technique can be applied to calculate a one-loop amplitude with arbitrary number of external legs

  32. Summary • Still many branches to explore in representations of amplitudes • The combination of the unitarity-based method and on-shell recursion relations gives a powerful and practical method for a wide variety of QCD calculations needed for LHC physics • Lots of important calculations are now feasible, and are awaiting physicists eager to do them!

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