The structure of IR divergences in celestial gluon amplitudes

Gonzalez, Hernan A.; Rojas, Francisco

Abstract

The all-loop resummation of SU(N) gauge theory amplitudes is known to factorize into an IR-divergent (soft and collinear) factor and a finite (hard) piece. The divergent factor is universal, whereas the hard function is a theory-dependent quantity. We prove that this factorization persists for the corresponding celestial amplitudes. Moreover, the soft/collinear factor becomes a scalar correlator of the product of renormalized Wilson lines defined in terms of celestial data. Their effect on the hard amplitude is a shift in the scaling dimensions by an infinite amount, proportional to the cusp anomalous dimension. This leads us to conclude that the celestial-IR-safe gluon amplitude corresponds to a expectation value of operators dressed with Wilson line primaries. These results hold for finite N. In the large N limit, we show that the soft/collinear correlator can be described in terms of vertex operators in a Coulomb gas of colored scalar primaries with nearest neighbor interactions. In the particular cases of four and five gluons in planar N=4 SYM theory, where the hard factor is known to exponentiate, we establish that the Mellin transform converges in the UV thanks to the fact that the cusp anomalous dimension is a positive quantity. In other words, the very existence of the full celestial amplitude is owed to the positivity of the cusp anomalous dimension.

Más información

Título de la Revista: Journal of High Energy Physics (JHEP)
Volumen: 2021
Número: 6
Fecha de publicación: 2021
Página de inicio: 1
Página final: 29
URL: https://link.springer.com/article/10.1007%2FJHEP06%282021%29171
Notas: This paper has been published in the Journal of High Energy Physics (JHEP) and it is in the process of being available online. The DOI is 10.1007/JHEP06(2021)171