Abstract
The transition between the broken and unbroken phases of massive gauge theories, namely the rearrangement of longitudinal and Goldstone degrees of freedom that occurs at high energy, is not manifestly smooth in the standard formalism. The lack of smoothness concretely shows up as an anomalous growth with energy of the longitudinal polarization vectors, as they emerge in Feynman rules both for real on-shell external particles and for virtual particles from the decomposition of the gauge field propagator. This makes the characterization of Feynman amplitudes in the high-energy limit quite cumbersome, which in turn poses peculiar challenges in the study of Electroweak processes at energies much above the Electroweak scale. We develop a Lorentz-covariant formalism where polarization vectors are well-behaved and, consequently, energy power-counting is manifest at the level of individual Feynman diagrams. This allows us to prove the validity of the Effective $W$ Approximation and, more generally, the factorization of collinear emissions and to compute the corresponding splitting functions at the tree-level order. Our formalism applies at all orders in perturbation theory, for arbitrary gauge groups and generic linear gauge-fixing functionals. It can be used to simplify Standard Model loop calculations by performing the high-energy expansion directly on the Feynman diagrams. This is illustrated by computing the radiative corrections to the decay of the top quark.
Highlights
We study the implications of these identities on the amputated Feynman amplitudes, deriving “generalized Ward identities” that are the analog of the familiar QED Ward identities kμAμ = 0
The custodial SU(2)c symmetry implies that the singlet h does not mix with the Wμa and πa triplets, and the two-point functions in the W /π sector are proportional to the identity in the custodial indices space
The equality comes from expanding the product and noticing that in each monomial the amputated amplitude is contracted with r = 0, · · ·, n powers of K, while the remaining n − r external legs are contracted with the standard polarization vectors
Summary
Studying Electroweak physics in reactions where the available center of mass energy E is much larger than the Electroweak scale m ∼ mW,Z is of both practical and theoretical interest. The standard longitudinal polarization vectors need to be replaced with well-behaved ones in off-shell amplitudes because we need power-counting for the latter diagrams in order to approach factorization problems, as we discussed. This has the purpose of illustrating the formalism and outlining the advantages of a manifest power-counting rule, and of verifying in non-trivial examples that our approach produces results that are exactly identical to the standard ones.
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