The heat conductivity () and the thermal diffusivity (a) of reacting glass batch, or melter feed, control the heat flux into and within the cold cap, a layer of reacting material floating on the pool of molten glass in an all-electric continuous waste glass melter. After previously estimating of melter feed at temperatures up to 680 degrees C, we focus in this work on the (T) function at T>680 degrees C, at which the feed material becomes foamy. We used a customized experimental setup consisting of a large cylindrical crucible with an assembly of thermocouples, which monitored the evolution of the temperature field while the crucible with feed was heated at a constant rate from room temperature up to 1100 degrees C. Approximating measured temperature profiles by polynomial functions, we used the energy equation to estimate the (T) approximation function, which we subsequently optimized using the finite-volume method combined with least-squares analysis. The heat conductivity increased as the temperature increased until the feed began to expand into foam, at which point the conductivity dropped. It began to increase again as the foam turned into a bubble-free glassmelt. We discuss the implications of this behavior for the mathematical modeling of the cold cap.