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Soft fragmentation on the celestial sphere

Duff Neill, Felix Ringer

2020Journal of High Energy Physics19 citationsDOIOpen Access PDF

Abstract

A bstract We develop two approaches to the problem of soft fragmentation of hadrons in a gauge theory for high energy processes. The first approach directly adapts the standard resummation of the parton distribution function’s anomalous dimension (that of twist-two local operators) in the forward scattering regime, using k T -factorization and BFKL theory, to the case of the fragmentation function by exploiting the mapping between the dynamics of eikonal lines on transverse-plane to the celestial-sphere. Critically, to correctly resum the anomalous dimension of the fragmentation function under this mapping, one must pay careful attention to the role of regularization, despite the manifest collinear or infra- red finiteness of the BFKL equation. The anomalous dependence on energy in the celestial case, arising due to the mismatch of dimensionality between positions and angles, drives the differences between the space-like and time-like anomalous dimension of parton densities, even in a conformal theory. The second approach adapts an angular-ordered evolution equation, but working in 4 − 2 ϵ dimensions at all angles. The two approaches are united by demanding that the anomalous dimension in 4 − 2 ϵ dimensions for the parton distribution function determines the kernel for the angular-ordered evolution to all orders.

Topics & Concepts

PhysicsResummationPartonEikonal equationParticle physicsCurse of dimensionalityDistribution functionFragmentation (computing)HadronScatteringDGLAPGauge theoryLarge Hadron ColliderDimension (graph theory)GluonFunction (biology)Fragmentation functionTheoretical physicsKernel (algebra)Eikonal approximationGauge (firearms)Quantum chromodynamicsAttractorStatistical physicsHigh-Energy Particle Collisions ResearchParticle physics theoretical and experimental studiesQuantum Chromodynamics and Particle Interactions