Kaon GTMDs in the Dyson-Schwinger equations using contact interaction

TL;DR

This paper investigates the kaon GTMDs using Dyson-Schwinger equations with contact interaction, revealing detailed parton distributions, form factors, and spin-orbit correlations within the kaon structure.

Contribution

It provides a comprehensive calculation of kaon GTMDs, GPDs, TMDs, and Wigner distributions within a covariant Dyson-Schwinger framework, including spin-orbit correlations and impact parameter distributions.

Findings

Kaon GTMDs and GPDs are computed using Dyson-Schwinger equations.

Wigner distributions for different quark polarizations are obtained.

Spin-orbit correlations and impact parameter distributions are analyzed.

Abstract

An array of the kaon twist-two, three, four generalised transverse momentum dependent parton distributions (GTMDs) has been investigated within the framework of covariant and confining Dyson-Schwinger equations using contact interaction. GTMDs are of great significance as they encompass information regarding both the generalised parton distributions (GPDs) and the transverse momentum dependent parton distributions (TMDs), thus being considered as the parent distribution. From GTMDs, we can derive the twist-two, three, four GPDs and TMDs. GPDs are obtained through the integration of $\bm{k}_{\perp}$ from GTMDs, with a focus on the twist-two GPDs. The first Mellin moments of GPDs yield the form factors of local currents. The second Mellin moments of vector GPDs are related to gravitational form factors. The Wigner distribution can be obtained from a Fourier transform in the transverse space of the GTMDs at skewedness parameter $\xi=0$. The Wigner distributions of an unpolarized, longitudinally polarized, and transversely polarized quark inside the kaon have been calculated. The spin-orbit correlations between a hadron and a quark can be explained based on the phase-space average of Wigner distributions. We investigate the correlation between the longitudinal spin and orbital angular momentum of valence quarks within the pion and kaon. Our findings reveal that $C_z^{u,K}=-0.336$, $C_z^{s,K}=0.242$, and $C_z^{u,\pi}=-0.374$. The parton distribution function in impact parameter space can be derived from the Wigner distribution. The study focuses on the light-front transverse-spin distributions $\rho_u^1\left(\bm{b}_{\bot },\bm{s}_{\perp}\right)$ and $\rho_u^2\left(\bm{b}_{\bot },\bm{s}_{\perp}\right)$, which exhibit distortions, and we calculate their average shift.