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Massive Gravity from Double Copy

High Energy Physics - Theory 2021-09-09 v3

Abstract

We consider the double copy of massive Yang-Mills theory in four dimensions, whose decoupling limit is a nonlinear sigma model. The latter may be regarded as the leading terms in the low energy effective theory of a heavy Higgs model, in which the Higgs has been integrated out. The obtained double copy effective field theory contains a massive spin-2, massive spin-1 and a massive spin-0 field, and we construct explicitly its interacting Lagrangian up to fourth order in fields. We find that up to this order, the spin-2 self interactions match those of the dRGT massive gravity theory, and that all the interactions are consistent with a Λ3=(m2MPl)1/3\Lambda_3= (m^2 M_{Pl})^{1/3} cutoff. We construct explicitly the Λ3\Lambda_3 decoupling limit of this theory and show that it is equivalent to a bi-Galileon extension of the standard Λ3\Lambda_3 massive gravity decoupling limit theory. Although it is known that the double copy of a nonlinear sigma model is a special Galileon, the decoupling limit of massive Yang-Mills theory is a more general Galileon theory. This demonstrates that the decoupling limit and double copy procedures do not commute and we clarify why this is the case in terms of the scaling of their kinematic factors.

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Cite

@article{arxiv.2004.07853,
  title  = {Massive Gravity from Double Copy},
  author = {Arshia Momeni and Justinas Rumbutis and Andrew J. Tolley},
  journal= {arXiv preprint arXiv:2004.07853},
  year   = {2021}
}

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Published version

R2 v1 2026-06-23T14:54:18.044Z