UV massive resonance from IR double copy consistency

From the perspective of effective field theory (EFT), Wilson coefficients of the low energy theory are determined by integrating out modes of the full ultraviolet (UV) theory. The spectrum can be in principle resummed if one has access to all available infrared (IR) coefficients at low energies. In...

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Bibliographic Details
Published in:Physical review. D 2024-03, Vol.109 (6), Article 065006
Main Authors: Carrasco, John Joseph M., Pavao, Nicolas H.
Format: Article
Language:English
Subjects:
effective field theory
field & string theory models & techniques
gauge theory techniques
gauge-gravity dualities
perturbative QCD
phenomenology
PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
scattering amplitudes
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Summary:From the perspective of effective field theory (EFT), Wilson coefficients of the low energy theory are determined by integrating out modes of the full ultraviolet (UV) theory. The spectrum can be in principle resummed if one has access to all available infrared (IR) coefficients at low energies. In this work we show that there exists a general class of consistent massive resonance double-copy (CMRDC) models where UV massive residues are reconstructed through double-copy consistency conditions between the IR Wilson coefficients of the full EFT expansion. Through a color-dual bootstrap, we find surprisingly that double-copy consistency alone introduces the kinematic factors of CMRDC models that soften high energy behavior by exponentiating color-dual contacts. This bootstrap suggests that our massive resonance paradigm is an inevitable consequence of the duality between color and kinematics, thereby providing a path towards emergent UV structure directly from the IR. We then demonstrate how CMRDC models can capture a spectrum of massive modes compatible with general multiplicity, and use Padé extrapolation to solve the inverse problem of identifying massive UV resonance from a small number of IR Wilson coefficients.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.109.065006