Glauber quark and gluon contributions to quark energy loss at next-to-leading order and next-to-leading twist

Abstract

The higher-twist formalism is used at O(α2s) to compute all possible medium-induced single-scattering emission kernels for an incoming highly energetic and virtual quark traversing the nuclear environment. The effects of the heavy-quark mass scale are taken into account [Phys. Rev. C 94, 054902 (2016)] both in the initial state as well as in the final state, along with interactions involving both in-medium Glauber gluons and quarks [Nucl. Phys. A 793, 128 (2007)], as well as coherence effects [Phys. Rev. C 105, 024908 (2022)]. As this study is a continuation of our work on medium-induced photon production [Phys. Rev. C 112, 025204 (2025)], the general factorization procedure for e-A deep-inelastic scattering is still used. An incoming quark energy loss in the nuclear medium yields four possible scattering kernels Ki with the following final states: (i) q+g, (ii) g+g, (iii) q+q', where the quark q may have a flavor different from the antiquark q', and (iv) q+q', where, again, q may have a flavor different from q'. The collisional kernels include full phase factors from all non-vanishing diagrams and complete first-order derivative in the longitudinal direction (k-) as well as second-order derivative in the transverse momentum (k) gradient expansion. Furthermore, in-medium parton distribution functions and the related jet transport coefficients have a hard transverse-momentum dependence (of the emitted quark or gluon) present within the phase factor.