Abstract
We recently introduced the concept of a "spacer salt" that creates structural heterogeneity and intermediate range order. Put simply, a fully networked salt melt, such as LaCl(3) or UCl(3), becomes disrupted by the introduction of ions that do not participate in the network. One of the results of this disruption is the experimental observation of two characteristic distances between the multivalent cations: the shorter "in-network" distance and the longer "across-network" distance spaced by the low-valency salt. The longer characteristic distance, absent if there is no spacer salt, is the culprit for a new first sharp diffraction peak in scattering experiments. Intuitively, it would appear to follow from this analysis that higher concentrations of the lower-valency salt would further separate multivalent cations, resulting in a shift to lower q values of this first sharp diffraction peak. We will show experimentally and computationally that this is not always the case because multiple other factors enter into play.