Medium-modified jet shapes are investigated using a linear Boltzmann transport model for event-by-event simulations of $\gamma$-jet productions in heavy-ion collisions.
The asymmetry ($A_N^{\vec{n}}$) localizes the initial transverse positions of the jets while the different selection of the jet transverse momentum ($p_T^{jet}$) exhibits the initial longitudinal positions. With the 2-dimensional jet tomography, our numerical results indicate that the in-cone transverse momentum is transported to the large angle away from the jet axis due to jet quenching in central Pb+Pb collisions at 5.02 TeV.
Furthermore, the transverse momentum inside the jet cone behaves with an asymmetric distribution as the gradient of the jet transport coefficient ($\hat{q}$) increases.