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Trees in N=8 SUGRA and Loops in N=4 SYM. Congkao Wen based in part on J.Drummond, M.Spradlin, and A.Volovich, 0808.1054, 0812.4767, 0901.2363 Durham University April 2nd, 2009. 1. Outline. N=8 Supergravity: Review of tree level S-matrix in N=4 SYM. Drummond, Henn (2008)
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Trees in N=8 SUGRA and Loops in N=4 SYM Congkao Wen based in part on J.Drummond, M.Spradlin, and A.Volovich, 0808.1054, 0812.4767, 0901.2363 Durham University April 2nd, 2009 1
Outline N=8 Supergravity: • Review of tree level S-matrix in N=4 SYM. Drummond, Henn (2008) • Tree level S-matrix in N=8 SUGRA. Drummond, Spradlin, Volovich, CW (2009) • New understanding for MHV gravity amplitude. Spradlin, Volovich, CW(2008) N=4 Super Yang-Mills: • All loop BDS ansatz and leading singularity method. Anastasiou,Bern,Dixon,Kosower(2003), Bern,Dixon,Smirnov(2005) Cachazo, Skinner(2008), Cachazo(2008), Cachazo, Spradlin, Volovich(2008) • Three-loop five-point amplitude. Spradlin, Volovich, CW (2008) 2
We try to solve the simplest problem of the “simplest quantum field theory”. N=8 super gravity With two definitions: • The simplest, but very nontrivial, problem of a quantum • field theory is the all tree level scattering amplitude. • The simplest quantum field theory is N=8 SUGRA. • Arkani-Hamed, Cachazo, Kaplan(2008) 3
The simplest problem is not really simple: Look at the literature: • There are a few different formulas for MHV amplitude. The first one was conjectured by Berend, Giele and Kuijf 20 years ago, which is far more complicated than Parke-Taylor formula of N=4 SYM. • Beyond MHV, the situation is of course worse. There is no general formula. In principle, KLT relation may be used to find the desired amplitude. 4
Britto, Cachazo, Feng & Witten An-k+1 An Ak+1 Basic tool BCFW recursion relations Ak+1 and An-k+1 are on-shelltree amplitudes with fewer legs, and with momenta shifted by a complex amount. Having a recursion is great, having a solution is even better!
All tree-level amplitudes In N=4 SYM Drummond, Henn 0808.2475 Use supersymmetric version of BCFW recursion relations and dual superconformal symmetry as guide. All tree-level solution: is a dual conformal invariant factor. Drummond,Henn, Korchemsky,Sokatchev(2008) Split helicity gluon amplitude (- - - - - - +++++) was solved byBritto, Feng, Roiban, Spradlin, Volovich(2005)
Definition of where the chiral spinor is given by For the dual coordinates we use 7
Examples NMHV: NNMHV: NNNMHV:
Tree level in N=8 SUGRA Drummond,Spradlin,Volovich,CW,0901,2363 Now we want to solve the BCFW recursion relation for N=8 SUGRA. Our results for N=8 SUGRA: ‘Gravity factor’ G is not dual conformal invariant. We find the “KLT relation” from BCFW.
Basic Ideas • Difficulties: • Gravity amplitudes are not color ordered. Actually there is no such • a thing called color. • There is no dual superconformal invariant to guide us. Introduce an ordered ‘gravity subamplitude’ Then we find the physic amplitude via (Supersymmetry is important here)
The subamplitude can be calculated by BCFW relations! The extra is the reason for gravity factor G. Now, the major job is to find the gravity factor G.
Examples Actually, the MHV amplitude in this form was found by Elvang & Freedman: (Elvang, Freedman (2007)) 5-point NMHV: 14
For NMHV, we found in 0901.2363that with where and
General formulas for , which will be important beyond NMHV level. NNMHV: 16
with: and Finally
Numerical check on 6-point NMHV amplitude We have checked numerically our expression agrees with other representations in literatures, see for example: Cachazo, Svrcek (2005), Bianchi, Elvang, & Freedman(2008) 18
Summary We find a solution to the recursion of the form and a specific procedure for writing down any gravity factor G. The expressions we have found can certainly be used in loop supergravity amplitudes by applying generalized unitarity technique in a manifestly supersymmetric way. Bern,Dixon,Dunbar,Kosower(1994) Arkani-Hamed,Cachazo,Kaplan(2008) Brandhuber, Spence, & Travaglini(2008) Drummond,Henn,Korchemsky,Sokatchev(2008) Elvang,Freedman,Kiermaier(2008)
MHV Revisited Spradlin,Volovich,CW,0812.4767 There are a few different MHV formulas in the literatures: • BGK formula conjectured by Berend, Giele and Kuijf 20 years ago. • BBST formula from BCFW relations. • Elvang & Freedman formula1 from BCFW relations, • EF formula2 conjectured by Elvang & Freedman, and equivalent • to one by Bern, Carrasco, Forde, Ita & Johansson. • 5. Mason & Skinner formula from twistor string theory. Berend, Giele, & Kuijf (2007) Bedford, Brandhuber, Spence, & Travaglini(2005) Elvang, Freedman(2007) Bern, Carrasco, Forde, Ita & Johansson(2007) Mason,Skinner(2008)
Divide all the formulas into two classes: • (n-2)!-term formulas: • BBST formula • Elvang & Freedman formula1 == ?? • (n-3)!-term formulas: • BGK formula • Elvang & Freedman formula2 • Mason & Skinner formula Of course, we can check numerically that all these formulas agree, but we would like an analytic understanding.
Bonus relation M(z) ~ 1/z^2 leads to one more relation: Benincasa,Boucher-Veronneau,Cachazo(2007) Arkani-Hamed, Kaplan(2008) Arkani-Hamed, Cachazo, Kaplan(2008) Besides BCFW recursion relation, we also have the bonus relation, Use the second equation, we can delete M_3 in the first equation. Apply this recursively, we can reduce (n-2)!-term formulas to (n-3)!-term formulas.
The Results Using the bonus relations, we analytically proved all five MHV formulas satisfy BCFW recursion relations, namely all of them are equivalent. As a byproduct, we also found a new MHV formula by simplifying (n-2)!-term BBST formula to a (n-3)!-term formula.
Loops in N=4 SYM • There are many remarkable properties of N=4 SYM scattering amplitude have been discovered. One of the discoveries will be relevant to our discussion is the BDS ansatz. Anastasiou,Bern,Dixon,Kosower(2003), Bern,Dixon,Smirnov(2005) The ansatz needs to be modified beyond five points. Alday, Maldacena(2007), Bern, Dixon, Kosower, Roiban, Spradlin, Vergu, Volovich(2008) Drummond, Henn, Korchemsky, Sokachev(2008)
Three-loop five-point amplitude Spradlin, Volovich, CW, 0808.1054 BDS relation: Use leading singularity method to determine integral coefficients, then check with BDS relation to determine N1 & N2 numerically. 25
Leading singularities Cachazo, Skinner(2008) Cachazo(2008) Cachazo, Spradlin, Volovich(2008) • The leading singularity method: • a natural basis of integral is provided. • the coefficients are determined by solving simple linear equations. • and the linear equations are easy to write down by hand. (for MHV • at least) • Leading singularity method is refinement of • generalized unitarity (Bern, Dixon, Dunbar, Kosower), (Britto, Cachazo, Feng)and maximal cuts (Bern, Carrasco, Johansson, Kosower)Basic idea: Feynman diagrams possess singularity which must be • reproduced by any representation of the amplitude in terms of simpler • integrals. For the maximal supersymmetric theory, it is conjectured that • the whole amplitude is determined by the leading singularity. 26
Collapse and expansion rules Collapse rule Expansion rule
Reduce loops to tree Example: Natural integrals related to this topology: L’s are coefficients of integrals
Linear equations of the coefficients Example: Solutions of r : We can simply solve it to get the coefficients. Actually, there are more equations than variables. strong consistency checks!
Then we numerically evaluate the following nine dual conformal integrals: and check with BDS relation, we find Remark: We have only evaluated obstruction P, not full amplitude. Cachazo, Spradlin, Volovich(2006)
Summary An algorithm for writing down explicit formulas for all tree amplitudes in N=8 super gravity. All gravity MHV formulas are equivalent and a new MHV formula. Full coefficients, both parity even and parity odd parts, of three-loop five-point amplitude in N=4 SYM are found by using leading sigularity. 32