As a potential alternative to traditional fossil fuels, nuclear energy plays an important role in building a safe and reliable energy supply system and addressing climate change issues. (1,2) The large-scale development of nuclear energy has raised higher demands for the supply of nuclear fuel. (3) It has been widely reported that thorium is 3–4 times more abundant than uranium in the earth’s crust. (4,5) The rich reserves of thorium and its military security have renewed the attention to thorium-based fuel. (5,6) Compared with the traditional uranium-based fuel cycle, the thorium-based fuel cycle shows outstanding advantages including high conversion efficiency, less Pu and minor actinide production, and good inherent safety. (7) Molten salt reactor (MSR) is regarded as the most ideal reactor system to realize the efficient utilization of thorium due to the possibility of online reprocessing and fuel breeding. (8) The identification of MSR as one of the potential systems to achieve the Generation-IV goal will promote the development of thorium fuel cycle. (9) Until now, Germany, the United States, the United Kingdom, India, China, etc., have carried out fundamental research and preliminary small-scale application tests related to the thorium fuel cycle, systematically proving the possibility of using thorium as nuclear fuel in reactors. (10–13) THTR-300 (Germany) and Fort St Vrain (USA) have achieved the production of 300 MWe power. (14) India has been working on the thorium fuel cycle due to the large thorium deposit. Considerable experience is accumulated in the utilization of thorium in engineering-scale facilities under the guidance of the three-stage program. (15) However, the significant challenges in the back end of the thorium fuel cycle restrict the industrial application of the thorium-based fuel cycle. The dissolution of thorium dioxide is more difficult than uranium oxide, so a small amount of HF addition to HNO3 is necessary, which will enhance the corrosion of stainless steel equipment. The chemical separation of uranium from spent fuel is also difficult because of the stability and invariable oxidation state of thorium. (16)

232Th as a fertile material undergoes neutron capture reaction and subsequent beta decays to produce fissile 233U, which is also accompanied by the production of highly radioactive 232U in small amounts. (16,17) For the bred 233U, the portion directly fissions in the reactor, while the nonfissional portion is removed from spent fuel and recycled as new fuel. Therefore, it is necessary to separate uranium from the irradiated thorium to enhance the utilization efficiency of thorium and reduce the volume of nuclear waste. (18) The separation of highly radioactive 232U produced by irradiation will also help to achieve the safe utilization of nuclear energy. Unlike uranium/plutonium separation in the reprocessing of uranium-based spent fuel, the uranium/thorium separation is more challenging because of the invariable oxidation state of thorium. (19) There has been extensive research in the separation of U(VI) and Th(IV), developing various technologies including solvent extraction, (20,21) adsorption, (22,23) ion exchange, (24) and so on, among which the solvent extraction method shows satisfactory performance because of the large processing capacity, high efficiency, and low cost. Until now, the Thorex (thorium–uranium extraction) process developed based on the Purex (plutonium uranium reduction and extraction) process is the only viable process to be applied in the industry, in which U(VI) and Th(IV) are coextracted by 5% tri-n-butyl phosphate (TBP) (Figure 1a) and then purified through ion exchange or precipitation. (25) The study on extractants possessing branched alkyl substituents such as tri-sec-butyl phosphate (TsBP) (26) and tris-2-ethylhexyl phosphate (TEHP) (27) has also been derived based on TBP. However, the organophosphorus extractants can only achieve the coextraction of U(VI) and Th(IV). In addition, the presence of phosphorus in the extractants will inevitably lead to secondary pollution because the extractants cannot be combusted completely...

Figure 1. Ligands mentioned in this work.

Scheme 1. Synthesized Routes of DEAPA and DOAPA Ligands

In this work, two new unsymmetrical acidic phenanthroline carboxamide ligands designed based on the hard–soft combination strategy were applied to the extraction of U(VI) from Th(IV) in nitric acid solutions. Both DEAPA and DOAPA show satisfactory performance in efficiency, selectivity, kinetics, and stripping, while DOAPA (DU(VI) = 1566 and SFU(VI)/Th(IV) = 1582, 4 M HNO3) gives higher DU(VI) values than DEAPA due to its stronger hydrophobicity. The experimental scheme of high-acidity extraction and low-acidity stripping can efficiently and easily achieve the separation of U(VI) and Th(IV). The results of slope analysis and spectroscopy titration studies consistently prove that the ligands complex with U(VI) in 1:1 stoichiometry while complex with Th(IV) in 1:1 and 1:2 stoichiometry...