MHV, CSW and BCFW: field theory structures in string theory amplitudes

Boels, Rutger H.; Larsen, Kasper J.; Obers, Niels A.; Vonk, Marcel

doi:10.1088/1126-6708/2008/11/015

Cited by 52 publications

(75 citation statements)

References 43 publications

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“…Applications of BCFW recursion to string amplitudes have demonstrated improved large z scaling compared to field theory amplitudes in certain kinematic regimes [17,18]. This not only validates the construction of a "bad shift" recursion formula without the requirement of N = 7 supersymmetry, but also enables the application of our previous argument to pursue even better termby-term large z bonus scaling.…”

Section: Bonus Scaling Of "Bad Shift" Bcfw For String Amplitudessupporting

confidence: 58%

Bonus scaling and BCFW inN=7supergravity

Liu

Shih

2015

Physics Letters B

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In search of natural building blocks for supergravity amplitudes, a tentative criteria is term-by-term bonus z^-2 large momentum scaling. For a given choice of deformation legs, we present such an expansion in the form of a BCFW representation in N=7 supergravity based on a special shift. We will show that this improved scaling behavior, with respect to the fully N=8 representation, is due to its automatic incorporation of the so called bonus relations.Comment: 16 pages, 2 figure

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Section: Bonus Scaling Of "Bad Shift" Bcfw For String Amplitudessupporting

confidence: 58%

Bonus scaling and BCFW inN=7supergravity

Liu

Shih

2015

Physics Letters B

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“…For example at six points two F 4 operators must generate exactly the same local polynomial as (F − ) 2 (F + ) 4 , and thus the coefficient of the latter must be the opposite of the coefficient of this polynomial. This is indeed exemplified by the DBI action as discussed in [27,28]. We will show that this will allow us to determine the exact coefficient for MHV operators with arbitrary multiplicity.…”

Section: Implications For Non-renormalization Theoremsmentioning

confidence: 77%

Exact coefficients for higher dimensional operators with sixteen supersymmetries

Chen

Huang

Wen

2015

J. High Energ. Phys.

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We consider constraints on higher-dimensional operators for supersymmetric effective field theories. In four dimensions with maximal supersymmetry and SU(4) Rsymmetry, we demonstrate that the coefficients of abelian operators F n with MHV helicity configurations must satisfy a recursion relation, and are completely determined by that of F 4 . As the F 4 coefficient is known to be one-loop exact, this allows us to derive exact coefficients for all such operators. We also argue that the results are consistent with the SL(2,Z) duality symmetry. Breaking SU(4) to Sp(4), in anticipation for the Coulomb branch effective action, we again find an infinite class of operators whose coefficients are determined exactly. We also consider three-dimensional N = 8 as well as six-dimensional N = (2, 0), (1, 0) and (1, 1) theories. In all cases, we demonstrate that the coefficient of dimension-six operator must be proportional to the square of that of dimension-four.

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“…Given that BCFW on-shell recursions [97] can in principle be applied string amplitudes [98][99][100], it would be interesting to relate the Berends-Giele recursion for Z-theory amplitudes to BCFW methods.…”

Section: Further Directionsmentioning

confidence: 99%

Non-abelian Z-theory: Berends-Giele recursion for the α ′-expansion of disk integrals

Mafra

Schlotterer

2017

J. High Energ. Phys.

110

159

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We present a recursive method to calculate the α -expansion of disk integrals arising in tree-level scattering of open strings which resembles the approach of Berends and Giele to gluon amplitudes. Following an earlier interpretation of disk integrals as doubly partial amplitudes of an effective theory of scalars dubbed as Z-theory, we pinpoint the equation of motion of Z-theory from the Berends-Giele recursion for its tree amplitudes. A computer implementation of this method including explicit results for the recursion up to order α 7 is made available on the website http://repo.or.cz/BGap.git.

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MHV, CSW and BCFW: field theory structures in string theory amplitudes

Cited by 52 publications

References 43 publications

Bonus scaling and BCFW inN=7supergravity

Bonus scaling and BCFW inN=7supergravity

Exact coefficients for higher dimensional operators with sixteen supersymmetries

Non-abelian Z-theory: Berends-Giele recursion for the α ′-expansion of disk integrals

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