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Queen Mary, University of London Nov. 9, 2011 Congkao Wen.

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Presentation on theme: "Queen Mary, University of London Nov. 9, 2011 Congkao Wen."— Presentation transcript:

1 Queen Mary, University of London Nov. 9, 2011 Congkao Wen

2

3  In the past several years there have been enormous progress in unraveling the structure of scattering amplitudes in gauge theory and gravity.

4  Conceptually, it leads beautiful mathematic structure of scattering amplitudes.

5  In the past several years there have been enormous progress in unraveling the structure of scattering amplitudes in gauge theory and gravity.  Conceptually, it leads beautiful mathematic structure of scattering amplitudes.  Practically, it makes some previous impossible calculations trivial, in particular precision calculations in QCD.

6 Inefficiency of traditional Feynman diagram calculation:

7

8  Gauge redundancy in every Feynman diagram.

9 Inefficiency of traditional Feynman diagram calculation:  Gauge redundancy in every Feynman diagram.  Fast-growing of # of Feynman diagrams:

10 Inefficiency of traditional Feynman diagram calculation:  Gauge redundancy in every Feynman diagram.  Fast-growing of Feynman diagrams:  Very complicated Feynman diagram calculations lead to very simple results.

11

12  The amplitudes with no/one negative helicity gluon/graviton vanish!

13  The first non-trivial one is called MHV amplitude with two negative helicity gluons/gravitons.

14  The amplitudes with no/one negative helicity gluon/graviton vanish!  The first non-trivial one is called MHV amplitude with two negative helicity gluons/gravitons.  NMHV, NNMHV, and so on.

15  Only color-ordered partial amplitudes will be considered,

16  Spinor helicity formalism: by using the on-shell condition

17  Only color-ordered partial amplitudes will be considered,  Spinor helicity formalism: by using the on-shell condition  Lorentz invariants are defined as

18  Five-gluon tree-level amplitude of QCD

19

20  The result obtained from traditional methods

21

22  The following contains all the physical content as the above formula:

23  The partial amplitudes:

24

25  Dress it up with colors and sum over permutations to obtain the full answer

26  The partial amplitudes:  Dress it up with colors and sum over permutations to obtain the full answer

27

28  The ideas and techniques are best understood with SUSY.

29  BCFW recursion relations for N=4 & N=8 were solved, which can be used as solutions of QCD and gravity.

30  The ideas and techniques are best understood with SUSY.  BCFW recursion relations for N=4 & N=8 were solved, which can be used as solutions of QCD and gravity.  QCD amplitudes can be decomposed into simpler ones

31  Recursion relations: [Britto, Cachazo, Feng & Witten, 04’, 05’]

32  Recursion relations: [Britto, Cachazo, Feng & Witten, 04’, 05’] Reduce higher-point amplitudes into lower-point ones

33  Recursion relations: [Britto, Cachazo, Feng & Witten, 04’, 05’] Reduce higher-point amplitudes into lower-point ones AnAn A k+1 A n-k+1

34  Recursion relations: [Britto, Cachazo, Feng & Witten, 04’, 05’] Reduce higher-point amplitudes into lower-point ones  Recursion is great, having solution is even better. AnAn A k+1 A n-k+1

35  First non-trivial case, MHV amplitude [Parke Taylor,86’]

36  All Non-MHV amplitudes [Drummond, Henn 08’]

37  First non-trivial case, MHV amplitude [Parke Taylor,86]  All Non-MHV amplitudes [Drummond, Henn 08’]  N=8 SUGRA was also solved similarly [Drummond, Spradlin, Volovich, CW, ’09]

38  BCFW recursion relation can be generalized to loop-level to obtain the loop integrand [Arkani-Hamed, Bourjaily, Cachazo, Caron-Huot, Trnka, 10’]

39  BCFW recursion relation can be generalized to loop-level to obtain the loop integrand [Arkani-Hamed, Bourjaily, Cachazo, Caron-Huot, Trnka, 10’]

40  CSW rule is a Witten's twistor-string theory inspired technique of "sewing" MHV amplitudes together to build arbitrarily tree amplitudes: [Cachazo, Svrcek, Witten, 04’]

41

42  Nothing prevents us to form a loop in CSW diagrams: [Brandhuber, Spence, Travaglini, 04’]

43

44  Amplitudes decomposed into coefficients multiplying scalar integrals and rational terms:

45

46  The coefficients can be determined by unitarity cuts.

47  Amplitudes decomposed into coefficients multiplying scalar integrals and rational terms:  The coefficients can be determined by unitarity cuts.  The rational part can be compute by recursion relations.

48

49  Abstract Symmetries are often helpful in practical calculations.

50  Dual (super)conformal symmetry exists at planar limit, which is invisible in Lagrangian.

51  Abstract Symmetries are often helpful in practical calculations.  Dual (super)conformal symmetry exists at planar limit, which is invisible in Lagrangian.  The symmetry acts on dual coordinates

52  Abstract Symmetries are often helpful in practical calculations.  Dual (super)conformal symmetry exists at planar limit, which is invisible in Lagrangian.  The symmetry acts on dual coordinates  Conformal symmetry and dual conformal symmetry comprise two lowest levels of a Yangian symmetry. [Drummond, et al, 08’][Drummond et al, 09’][Arkani-Hamed, 10’]

53

54  Dual conformal symmetry has anomaly at loop level.

55  Anomaly equation allows us to determine 4 and 5-point amplitudes to all loop order. [Drummond, Henn, Korchemsky, E.Sokatchev, 08’]

56  Dual conformal symmetry has anomaly at loop level.  Anomaly equation allows us to determine 4 and 5-point amplitudes to all loop order. [Drummond, Henn, Korchemsky, E.Sokatchev, 08’]  All-loop amplitudes can be written as [Bern, Dixon, Smirnov, 05’] BDS ansatz + Remainder function.

57

58  Expectation value of Light-like Wilson loop in dual space is equivalent to scattering amplitudes. [Alday, Maldacena, 07’] [Drummond et al, 08’] [Brandhuber, Heslop, Travaglini, 08’] [BHT & Spence, 09’]

59  Correlation function of some operators with Light-like limit is equivalent to scattering amplitudes. [Alday, et al 10’]

60  Expectation value of Light-like Wilson loop in dual space is equivalent to scattering amplitudes. [Alday, Maldacena, 07’][Drummond et al, 08’] [Brandhuber, Heslop, Travaglini, 08’] [BHT & Spence, 09’]  Correlation function of some operators with Light-like limit is equivalent to scattering amplitudes. [Alday et al, 10’]  It helps computing the scattering amplitudes: OPE of Wilson loop [Alday, Gaiotto, Maldacena, Sever, Vieria]

61  Witten’s twistor string theory: [Witten, 03’]

62 Scattering amplitudes are related to the curves in (super)twistor space.

63  Witten’s twistor string theory: [Witten, 03’] Scattering amplitudes are related to the curves in (super)twistor space.  Arkani-Hamed et al’s Grassmannian formalism: [Arkani-Hamed, Cachazo, Chueng, Kaplan, 09’]

64  Witten’s twistor string theory: [Witten, 03’] Scattering amplitudes are related to the curves in (super)twistor space.  Arkani-Hamed et al’s Grassmannian formalism: [Arkani-Hamed, Cachazo, Chueng, Kaplan, 09’] All-loop Planar amplitudes are associated with an contour integral defined with Grassmannian.

65  Witten’s twistor string theory: [Witten, 03’] Scattering amplitudes are related to the curves in (super)twistor space.  Arkani-Hamed et al’s Grassmannian formalism: [Arkani-Hamed, Cachazo, Chueng, Kaplan, 09’] All-loop Planar amplitudes are associated with an contour integral defined with Grassmannian.  Twistor string theory and Grassmannian formulation are closely related to each other. [Bourjaily, Trnka, Volovich, CW, 10’]

66

67  BCFW recursion relations and CSW rules make some previous impossible calculations trivial.

68  Numerical calculations on QCD.

69  BCFW recursion relations and CSW rules make some previous impossible calculations trivial.  Numerical calculations on QCD.  New symmetries in N=4 SYM.

70  BCFW recursion relations and CSW rules make some previous impossible calculations trivial.  Numerical calculations on QCD.  New symmetries in N=4 SYM.  Wilson loop/Correlation/Amplitude duality.

71  BCFW recursion relations and CSW rules make some previous impossible calculations trivial.  Numerical calculations on QCD.  New symmetries in N=4 SYM.  Wilson loop/Correlation/Amplitude duality.  Dual of S-matrix: Twistor string theory & Grassmannian formulation.

72  BCFW recursion relations and CSW rules make some previous impossible calculations trivial.  Numerical calculations on QCD.  New symmetries in N=4 SYM.  Wilson loop/Correlation/Amplitude duality.  Dual of S-matrix: Twistor string theory & Grassmannian formulation.  Much more to uncover.

73 Thank you!

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