 The study investigates the dynamics of photo-excited carriers and non-equilibrium phonons in graphene under a linear energy dispersion approximation by solving microscopic kinetic block equations. The pump and drift effects from the laser field as well as relevant scatterings, including Coulomb scattering with dynamic screening, are explicitly included. When the pump photon energy is high enough, the influence of the drift term is negligible, leading to an isotropic hot electron Femi distribution with separate conduction and valence band chemical potentials. However, when the pump photon energy is low, the drift term is important and leads to a net momentum transfer from the electric field to electrons, resulting in a drifted Femi distribution different from the one established under static electric fields. The study also shows that the auger process involving only diagonal terms of density matrices is forbidden by dynamic screening but proposes an auger process involving interband coherence, which contributes to carrier dynamics when the pump photon energy is low. Additionally, the anisotropically momentum resolved hot phonon temperatures due to linearly polarized light are investigated, revealing the underlying physics. This article was authored by B. Y. Sun and M. W. Wu. We are article.tv, links in the description below.