Light-front dynamic analysis of the longitudinal charge density using the solvable scalar field model in (1+1) dimensions

TL;DR

This paper uses light-front dynamics in a solvable scalar field model to analyze the meson form factor and longitudinal charge density, providing analytic results valid across all momentum transfer regions.

Contribution

It demonstrates the advantages of light-front dynamics for frame-independent amplitude calculations and derives analytic expressions for the form factor in a (1+1) dimensional model.

Findings

Analytic form factor results valid for both spacelike and timelike regions.

Verification of dispersion relations across all $q^2$.

Insights into transverse momentum effects and boost-invariant charge density.

Abstract

We investigate the electromagnetic form factor $F(q^2)$ of the meson by using the solvable $\phi^{3}$ scalar field model in $(1+1)$ dimensions. As the transverse rotations are absent in $(1+1)$ dimensions, the advantage of the light-front dynamics (LFD) with the light-front time $x^+ = x^0 + x^3$ as the evolution parameter is maximized in contrast to the usual instant form dynamics (IFD) with the ordinary time $x^0$ as the evolution parameter. In LFD, the individual $x^+$-ordered amplitudes contributing to $F(q^2)$ are invariant under the boost, i.e., frame-independent, while the individual $x^0$-ordered amplitudes in IFD are not invariant under the boost but dependent on the reference frame. The LFD allows to get the analytic result for the one-loop triangle diagram which covers not only the spacelike ($q^{2}<0$) but also timelike region ($q^{2}>0$). Using the analytic results, we verify that the real and imaginary parts of the form factor satisfy the dispersion relations in the entire $q^{2}$ space. Comparing with the results in $(3+1)$ dimensions, we discuss the transverse momentum effects on $F(q^2)$ . We also discuss the longitudinal charge density in terms of the boost invariant variable $\tilde z = p^+ x^-$ in LFD.