Abstract
We extract the leading Fock-state light front wave functions (LF-LFWFs) of both the light and heavy pseudoscalar mesons, e.g., the pion (at masses of 130 MeV, 310 MeV and 690 MeV), $\eta_c$ and $\eta_b$, from their covariant Bethe-Salpeter wave functions within the rainbow-ladder (RL) truncation. It is shown that the LF-LFWFs get narrower in $x$ (the longitudinal momentum fraction of meson carried by the quark) with the increasing current quark mass, and the leading twist parton distribution amplitudes (PDAs) inherit this feature. Meanwhile, we find in the pion the LF-LFWFs only contribute around 30\% to the total Fock-state normalization, indicating the presence of significant higher Fock-states within. In contrast, in the $\eta_c$ and $\eta_b$ the LF-LFWFs contribute more than $90$\%, suggesting the $Q\bar{Q}$ valence Fock-state truncation as a good approximation for heavy mesons. We thus study the 3-dimensional parton distributions of the $\eta_c$ and $\eta_b$ with the unpolarized generalized parton distribution function (GPD) and the transverse momentum dependent parton distribution function (TMD). Through the gravitational form factors in connection with the GPD, the mass radii of the $\eta_c$ and $\eta_b$ in the light-cone frame are determined to be $r_{E,{\rm LC}}^{\eta_c} =0.150$ fm and $r_{E,{\rm LC}}^{\eta_b} =0.089$ fm respectively.
Highlights
As a result of the Higgs mechanism [1,2], very large current quark mass differences abound in quantum chromodynamics (QCD), resulting in diverse hadronic phenomenon in the light and heavy sectors
It is shown that the leading Fock state light-front wave function (LF-LFWF) get narrower in x with the increasing current quark mass, and the leading twist parton distribution amplitudes inherit this feature
We study the leading Fock state light-front wave functions of the light and heavy pseudoscalar mesons, using a unified framework of rainbow-ladder Dyson-Schwinger– Bethe-Salpeter equations method (DS-BSEs) and the light-front projection method
Summary
As a result of the Higgs mechanism [1,2], very large current quark mass differences abound in quantum chromodynamics (QCD), resulting in diverse hadronic phenomenon in the light and heavy sectors. The present study is motivated in several directions: In the light quark sector, we study the LF-LFWFs of the pion at the physical mass ð≈130 MeVÞ and make predictions at testing masses of mπ 1⁄4 310 and 690 MeV The latter two cases are chosen as they are directly accessible in lattice simulations [22]. We report the ηc and ηb LFLFWFs determined for the first time from the DS-BSEs. In the heavy sector, we report the ηc and ηb LFLFWFs determined for the first time from the DS-BSEs Using these LFWFs, we analyze the PDAs of ηc and ηb and investigate their 3D parton structure with the help of GPDs and TMDs. This paper is organized as follows: In Sec. II, we introduce the DS-BSEs formalism and extract the LFLFWFs from the covariant BS wave functions.
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