Investigating Generalized Parton Distribution in Gravity Dual

TL;DR

This paper explores the non-perturbative structure of generalized parton distributions (GPDs) at small x using gravity dual models, revealing phase transitions and matching experimental data.

Contribution

It demonstrates that GPDs can be extracted from DDVCS amplitudes in strong coupling regimes via gravity duals, highlighting phase behavior and experimental agreement.

Findings

GPD is well-defined in the gravity dual framework.

Two phases identified in the imaginary part of DDVCS amplitude.

Qualitative agreement with HERA measurements.

Abstract

Generalized parton distribution (GPD) contains rich information of partons in a hadron, including transverse profile, and is also non-perturbative information necessary in describing a variety of hard processes, such as meson leptoproduction and double deeply virtual Compton scattering (DDVCS). In order to unveil non-perturbative aspects of GPD, we study DDVCS at small $x$ in gravitational dual description. Using the complex spin $j$-plane representation of DDVCS amplitude, we show that GPD is well-defined and can be extracted from the amplitude even in the strong coupling regime. It also turns out that the saddle point value in the $j$-plane representation plays an important role; there are two phases in the imaginary part of the amplitude of DDVCS and GPD, depending on relative position of the saddle point and the leading pole in the $j$-plane, and crossover between them is induced by the change of the kinematical variables. The saddle point value also directly controls kinematical variable dependence of many observables in one of the two phases, and indeed the dependence is qualitatively in nice agreement with HERA measurements. Such observation that the gravity dual shares basic properties of the real world QCD suggests that information from BFKL theory might be used to reduce error in the gravity dual predictions of the form factor and of GPD. This article also serves as a brief summery of a preprint arXiv:1105.2999.