The set of benchmark solutions used in the thermal radiative transfer community suffer some coverage gaps, in particular nonlinear, nonequilibrium problems. %Without denigrating the ingenuity or usefulness of any individual published benchmark, it is necessary to remark that the all of the extant non-equilibrium benchmarks require a linearization of the material coupling term. Also, there are no nonequilibrium, optically thick benchmarks. These shortcomings motivated the origination of a numerical method unfettered by preconditions of linearity and easily able to converge on smooth optically thick problems, a moving mesh Discontinuous Galerkin (DG) framework that utilizes an uncollided source treatment. Having already proven this method on time dependent scattering transport problems, we present here solutions to non-equilibrium thermal radiative transfer problems for familiar linearized systems and more physical nonlinear systems in both optically thin and thick regimes, including both the full transport and the $S_2$/$P_1$ solution. Geometric convergence is observed for smooth sources at all times and some nonsmooth sources at late times when there is local equilibrium and accurate solutions are achieved for step sources when the solution is not smooth.