Solvation Dynamics of HEHEHP Ligand at the Liquid–Liquid Interface

Ta, An T.; Hegde, Govind A.; Etz, Brian D.; Baldwin, Anna G.; Yang, Yuan; Shafer, Jenifer C.; Jensen, Mark P.; Maupin, C. Mark; Vyas, Shubham

doi:10.1021/acs.jpcb.8b03165

Cited by 13 publications

(26 citation statements)

References 37 publications

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“…For example, these studies covered the ligands of BTPhen, 20 BTBP, 22 18-Crown-6, 53−56 tri-n-butyl phosphate (TBP), 57−59 calix [4]arene, 60 N,N-di(2-ethylhexyl)isobutyramide (DEHi-BA), 61 and 2-ethylhexylphosphonic acid mono-2-ethylhexyl ester (HEHEHP). 62 It is now established that the complexation of ligands with metal ions happened at the interface. The key influencing factors relevant to the composition of the extraction systems, for example, the effect of synergistic reagent and counter-ions, the nature of the diluents, the acidity of the aqueous phase, and their effect on the dynamics of extracted species and their migration behavior to cross the interface, have been also analyzed for specific model systems in earlier works, and it remains to enrich and generalize our understanding on these issues to assist the advancement of experimental studies.…”

Section: Discussionmentioning

confidence: 99%

“…To assist the development of LLExt protocols, in an earlier work, MD simulations have been carried out to study the biphasic behavior of extractants and the extracted complexes. For example, these studies covered the ligands of BTPhen, BTBP, 18-Crown-6, − tri- n -butyl phosphate (TBP), − calix[4]arene, N , N -di(2-ethylhexyl)isobutyramide (DEHiBA), and 2-ethylhexylphosphonic acid mono-2-ethylhexyl ester (HEHEHP) . It is now established that the complexation of ligands with metal ions happened at the interface.…”

Section: Discussionmentioning

confidence: 99%

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Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes

et al. 2020

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zotriazin-3-yl)-1,10-phenanthroline, denoted as L) has been considered as a promising extractant in lanthanide(III)/actinide(III) separation. Vast endeavors in its application put forward a compelling need on the understanding of the underlying mechanism in the liquid−liquid extraction. To address the issue of its dynamics in biphasic systems, we carried out molecular dynamics (MD) simulations of L and its complexes with a heavy f-block metal ion, americium(III) (Am 3+ ) in "oil"/water binary solvents. Two types of organic phases have been considered, differing in the presence of octanol in the bulk ndodecane or not, and the distribution of the solutes and their interfacial behaviors have been investigated. Two of the key factors that determine the efficiency of a liquid−liquid extraction protocol were delineated and discussed, that is, the appropriate ligand to enhance the lipophilicity of AmL complexes and appropriate way to form ion pairs to minimize the attraction between the complexes and aqueous phase. The simulations showed that the charge states of both ligand and AmL complexes were strongly correlated with their phase behavior, and the migration of neutral species was driven by van der Waals interactions while that of charged species by electrostatic interactions, indicating stronger lipophilicity of the former than the latter. The presence of octanol facilitated the migration of the ligand from the interface to the organic phase via hydrogen bond between its polar head and the ligand or the AmL complexes and constituted a polar core in the organic phase. This work bridged the widely used liquid−liquid extraction technique in chemistry to a fundamental chemical concept, that is, minimization of hydrophilicity and maximization of lipophilicity to facilitate phase transfer from the aqueous phase to the organic phase, and is expected to improve the understanding of dynamics of ligands and their complexes with metal ions and to contribute to the development of efficient protocols for phase transfer of target species.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes

et al. 2020

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“…Ab initio calculations were carried out using the Gaussian09 software package. 23 Geometry optimizations of HEHEHP and n-dodecane were taken from earlier work 13 while the structures of T2EHDGA and nitrate were optimized using the same level of theory (M06-2X//6-311G(2d,d,p)). Partial atomic charges (Table S1, Supporting Information) were obtained using the restrained electrostatic potential (RESP) method at MP2/cc-PVTZ// M06-2X/6-311G(2d,d,p) level of theory (Tables S1 and S2, Supporting Information).…”

Section: Methodsmentioning

confidence: 99%

“…Several solvent extraction processes have been developed to target this difficult separation including the SANEX, GANEX, and advanced TALSPEAK processes (acronyms are defined within the Supporting Information), as well as the recently developed Actinide-Lanthanide Separation Process (ALSEP). 5,6,9,13 However, each of these processes have drawbacks at the industrial scale.…”

Section: Introductionmentioning

confidence: 99%

Dynamic and Solvation Behaviors of ALSEP Organic Ligands

Jensen

Vyas

2019

J. Phys. Chem. B

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The Actinide-Lanthanide Separation Process (ALSEP) is a solvent extraction approach for separating relevant trivalent minor actinides (e.g., americium and curium) from used nuclear fuel. However, relatively slow kinetics in the stripping step of the process restricts process throughput when scaled for industrial implementation. To assist in identifying specific kinetic barriers associated with the separation, the solvation and dynamic behaviors of the two organic extractants in the current ALSEP implementation, N,N,N′,N′-tetra(2ethylhexyl)diglycolamide (T2EHDGA) and 2-ethylhexylphosphonic acid mono-2-ethylhexyl ester (HEHEHP), were probed through molecular dynamics (MD) simulations. The simulations examined the effects of extractant and nitric acid concentration on the interfacial behavior of the extractants in three solvent systems (n-dodecane, water, and n-dodecane + water). Solvation analyses of T2EHDGA revealed expected amphiphilic behavior in pure solvent systems. In a nitric-acid-free biphasic solvent, it was found that T2EHDGA expressed similar interfacial conformations as HEHEHP, suggesting that a parallel-like configuration, relative to the interface, is adopted at low concentrations. When HNO 3 was introduced to biphasic systems containing a single molecule of extractant, HEHEHP was observed to retain a relatively parallel orientation while the T2EHDGA orientation was no longer affected by the presence of the interface. At bulk extractant concentrations, representative of the ALSEP process, the presence of nitric acid had minimal impact on the ligand orientation. Calculated diffusion constants showed that only some systems involving T2EHDGA were affected by the presence of acid.

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“…而二氯甲烷溶剂铺展的 P507 单分子膜中聚集体较少, 分子单体不能依靠 "晶核"快速聚并成聚集体 [16] . P507 分子在界面以单体形式或二聚体形式存在, 其极性端深入水相的角度和深度必定会存在差异, 这必然会影响到磷氧基团水化及其萃取水相离子的能力 [37] . 因此, 对聚集体或二聚体分子在界面如何排布和取向仍需深入研究.…”

Section: 亚相 Ph 和分子平均占据面积关联模型unclassified

Interfacial Behavior of Acidic Organophosphorus Extractant Monolayer at Air-Water Interface: Subphase pH and Spreading Solvent Effect

高振¹,

黄焜²,

杜林³

et al. 2019

Acta Chim. Sinica

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The interfacial properties of extractant molecules have a significant impact on their complexation reaction activity with rare earth ions at liquid-liquid interface during solvent extraction. Although it is known that acidic organophosphorus extractant exists mainly in the form of dimers in nonpolar organic solvent, the research on solvent extraction kinetics has pointed out that the extractant molecules should react with rare earth ions in the form of monomers at the interface. Therefore, understanding the existing forms of acidic organophosphorus extractant at the interface will help comprehend the interfacial reaction process in solvent extraction. Traditionally, the interfacial properties of the extractant molecules were investigated by measuring interfacial tension isotherms and calculating interfacial adsorption parameters. However, this method can not provide the information of interfacial active species and the aggregation behavior of them. In order to clarify the characteristics of the interfacial behavior of organic extractant molecules at the interface, the effect of subphase pH and the polarity of spreading organic solvent on the adsorption and aggregation behavior of P507 molecules at the air-water interface were investigated by surface pressure-area isotherms and infrared reflectance absorption spectroscopy (IRRAS) based on Langmuir monolayer technique. It was found that P507 monolayers spread by n-hexane at the air-water interface had a certain solubility in the subphase water due to the ionization of the polar groups of P507 molecules. And the solubility decreased as the subphase pH decreased. Thus, the surface pressure-area isotherms changed significantly due to the total amount of P507 molecules remaining on the surface of water changed with the subphase pH. When the subphase pH decreased below 2.0, the influence of the solubility of P507 molecules became inapparent and the amount of P507 molecules remaining on the surface of

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Solvation Dynamics of HEHEHP Ligand at the Liquid–Liquid Interface

Cited by 13 publications

References 37 publications

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes

Dynamic and Solvation Behaviors of ALSEP Organic Ligands

Interfacial Behavior of Acidic Organophosphorus Extractant Monolayer at Air-Water Interface: Subphase pH and Spreading Solvent Effect

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Solvation Dynamics of HEHEHP Ligand at the Liquid–Liquid Interface

Cited by 13 publications

References 37 publications

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe4-BTPhen and Its Am(III) Complexes

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe4-BTPhen and Its Am(III) Complexes

Dynamic and Solvation Behaviors of ALSEP Organic Ligands

Interfacial Behavior of Acidic Organophosphorus Extractant Monolayer at Air-Water Interface: Subphase pH and Spreading Solvent Effect

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Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes

Key Factors Determining Efficiency of Liquid–Liquid Extraction: Implications from Molecular Dynamics Simulations of Biphasic Behaviors of CyMe₄-BTPhen and Its Am(III) Complexes