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Micheau, C.; 上田 祐生; 元川 竜平; 阿久津 和宏*; 山田 悟史*; 山田 雅子*; Moussaoui, S. A.*; Makombe, E.*; Meyer, D.*; Berthon, L.*; et al.
Journal of Molecular Liquids, 401, p.124372_1 - 124372_12, 2024/05
被引用回数:1 パーセンタイル:65.37(Chemistry, Physical)Supramolecular organization of amphiphilic extractant molecules is involved in metal cation selectivity and separation kinetics during solvent extraction. The relationship between extractant associates/aggregates formed in the organic bulk phase and at the liquid-liquid interface is poorly understood even though it affects the extraction mechanism. The nanoscopic structures of the extraction systems N,N,N',N'-tetrahexylmalonamide (THMA) in toluene and N,N'-dibutyl-N,N'-dimethyl-2-tetradecylmalonamide (DBMA) in n-heptane, used for either Pd(II) or Nd(III) selective extraction from an acidic aqueous phase, were examined. These systems present markedly different affinity for Pd(II) and Nd(III), and extraction kinetics. Extractant organization in the organic bulk phase and at the interface were compared by small-angle X-ray scattering, interfacial tension, and neutron reflectivity. THMA in toluene forms small associates in the organic bulk phase and accumulates in a diffuse layer at the interface, decreasing Pd(II) coordination probability and resulting in slow extraction. DBMA in n-heptane forms large aggregates and a compact, dense interfacial layer, resulting in rapid Pd(II) and Nd(III) extraction. Thus, Pd(II) extraction is driven by interfacial coordination alone, whereas the incorporation of Nd(III) into the core of large aggregates governs Nd(III) extraction in the interfacial layer. These results suggest that the interface should be described as a nanoscale interphase containing a high extractant concentration compared with the organic bulk phase.
Micheau, C.; 上田 祐生; 元川 竜平; Moussaoui, S.*; Makombe, E.*; Daniel, M.*; Berthon, L.*; Bourgeois, D.*; 阿久津 和宏*
no journal, ,
The DIAMEX process aims to separate minor f-elements using malonamide as extractant molecules such as N,N'-dimethyl-N,N'-dibutyl-tetradecyl-malonamide (DBMA). Recently, Poirot studied the effect of n-heptane and toluene on the selectivity of DBMA between Pd and Nd and have conclude that Pd extraction is driven by coordination whereas Nd extraction is driven by extractant aggregation. More recently, a specific study on tetrahexylmalonamide (THMA) in toluene demonstrated a superior selectivity for Pd compared to DBMA. THMA molecular structure suggests poor aptitude for aggregation compared with DBMA, and has been much less characterized. Supramolecular features of two different solvent extraction systems based on malonamide extractants, THMA in toluene and DBMA in heptane, have been studied using characterization techniques dedicated to bulk organic phase organisation, ie. small angle X-ray scattering, and to interface characterization, ie. neutron reflectivity and interfacial tension.