Thenoyltrifluoroacetone (HTTA)-based extractions represent popular methods for separating microscopic amounts of transuranic actinides (i.e., Np and Pu) from macroscopic actinide matrixes (e.g. bulk uranium). It is well-established that this procedure enables +4 actinides to be selectively removed from +3, + 5, and +6 f-elements. However, even highly skilled and well-trained researchers find this process complicated and (at times) unpredictable. It is difficult to improve the HTTA extraction-or find alternatives-because little is understood about why this separation works. Even the identities of the extracted species are unknown. In addressing this knowledge gap, we report here advances in fundamental understanding of the HTTA-based extraction. This effort included comparatively evaluating HTTA complexation with +4 and +3 metals (M-IV = Zr, Hf, Ce, Th, U, Np, and Pu vs M-III = Ce, Nd, Sm, and Yb). We observed +4 metals formed neutral complexes of the general formula M-IV(TTA)(4). Meanwhile, +3 metals formed anionic MIII(TTA)4 species. Characterization of these M(TTA)(4)(x-) (x = 0, 1) compounds by UV-vis-NIR, IR, H-1 and F-19 NMR, single-crystal X-ray diffraction, and X-ray absorption spectroscopy (both near-edge and extended fine structure) was critical for determining that Np-IV(TTA)(4) and Pu-IV(TTA)(4) were the primary species extracted by HTTA. Furthermore, this information lays the foundation to begin developing and understanding of why the HTTA extraction works so well. The data suggest that the solubility differences between M-IV(TTA)(4) and M-III(TTA)(4)(-) are likely a major contributor to the selectivity of HTTA extractions for +4 cations over +3 metals. Moreover, these results will enable future studies focused on explaining HTTA extractions preference for +4 cations, which increases from Np-IV to Pu-IV, Hf-IV, and Zr-IV.