Strong Periodic Tendency of Trivalent Lanthanides Coordinated with a Phenanthroline-Based Ligand: Cascade Countercurrent Extraction, Spectroscopy, and Crystallography

Yang, Xiaofan; Ren, Peng; Yang, Qi; Geng, Jun-Shan; Zhang, Jinyu; Yuan, Liyong; Tang, Hongliang; Chai, Zhifang

doi:10.1021/acs.inorgchem.1c01035

Cited by 31 publications

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“…Since the antenna effect is extremely interesting from fundamental point of view, many theoretical and spectroscopic studies discussed the photophysical process of absorption of light, the excited state energy transfer from the ligand to the europium ion and the luminescent properties of these compounds [ 30 , 31 , 32 , 33 , 34 ]. Application-oriented investigations on phenanthroline-based complexes also demonstrated their importance for the advance technologies [ 35 , 36 , 37 , 38 , 39 , 40 ].…”

Section: Introductionmentioning

confidence: 99%

Luminescent Complexes of Europium (III) with 2-(Phenylethynyl)-1,10-phenanthroline: The Role of the Counterions

et al. 2021

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New antenna ligand, 2-(phenylethynyl)-1,10-phenanthroline (PEP), and its luminescent Eu (III) complexes, Eu(PEP)2Cl3 and Eu(PEP)2(NO3)3, are synthesized and characterized. The synthetic procedure applied is based on reacting of europium salts with ligand in hot acetonitrile solutions in molar ratio 1 to 2. The structure of the complexes is refined by X-ray diffraction based on the single crystals obtained. The compounds [Eu(PEP)2Cl3]·2CH3CN and [Eu(PEP)2(NO3)3]∙2CH3CN crystalize in monoclinic space group P21/n and P21/c, respectively, with two acetonitrile solvent molecules. Intra- and inter-ligand π-π stacking interactions are present in solid stat and are realized between the phenanthroline moieties, as well as between the substituents and the phenanthroline units. The optical properties of the complexes are investigated in solid state, acetonitrile and dichloromethane solution. Both compounds exhibit bright red luminescence caused by the organic ligand acting as antenna for sensitization of Eu (III) emission. The newly designed complexes differ in counter ions in the inner coordination sphere, which allows exploring their influence on the stability, molecular and supramolecular structure, fluorescent properties and symmetry of the Eu (III) ion. In addition, molecular simulations are performed in order to explain the observed experimental behavior of the complexes. The discovered structure-properties relationships give insight on the role of the counter ions in the molecular design of new Eu (III) based luminescent materials.

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Section: Introductionmentioning

confidence: 99%

Luminescent Complexes of Europium (III) with 2-(Phenylethynyl)-1,10-phenanthroline: The Role of the Counterions

et al. 2021

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“…Hard soft acid base theory categorizes the lanthanides as hard electron acceptors, which tend to have a high affinity toward hard O donors. 47 Similar to the Nd(III)–N(BLPhen) distances, Nd(III)–O(BLPhen) distances are also longer in the 2:1 complex than that in the 1:1 complex. Integration of RDFs in Figure 3 b shows that there are two BLPhen oxygen atoms around Nd(III) in the 1:1 complex and four BLPhen oxygen atoms around Nd(III) in the 2:1 complex, as the snapshots in Figure 2 indicate.…”

Section: Resultsmentioning

confidence: 79%

“…Hard soft acid base theory categorizes the lanthanides as hard electron acceptors, which tend to have a high affinity toward hard O donors. 47 Similar to the Nd(III)− N(BLPhen) distances, Nd(III)−O(BLPhen) distances are also longer in the 2:1 complex than that in the 1:1 complex. Integration of RDFs in Figure 3b shows that there are two 3.3.…”

Section: Introductionmentioning

confidence: 75%

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Atomistic Insights into Structure and Dynamics of Neodymium(III) Complexation with a Bis-lactam Phenanthroline Ligand in the Organic Phase

et al. 2022

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Rare-earth elements (REEs) such as neodymium are critical materials needed in many important technologies, and rigid neutral bis-lactam-1,10-phenanthroline (BLPhen) ligands show one of the highest extraction performance for complexing Nd(III) in REE uptake and separation processes. However, the local structure of the complexes formed between BLPhen and Nd(III) in a typical organic solvent such as dichloroethane (DCE) is unclear. Here, we perform first-principles molecular dynamics (FPMD) simulations to unveil the structure of complexes formed by BLPhen with Nd(NO 3 ) 3 in the DCE solvent. BLPhen can bind to Nd(III) in either 1:1 or 2:1 fashion. In the 1:1 complex, three nitrates bind to Nd(III) via the bidentate mode in the first solvation shell, leading to the formation of a neutral complex, [Nd(BLPhen)(NO 3 ) 3 ] 0 , in the organic phase. In contrast, there are two nitrates in the first solvation shell in the 2:1 complex, creating a charged complex, [Nd(BLPhen) 2 (NO 3 ) 2 ] + . The third nitrate was found to be far away from the metal center, migrating to the outer solvation shell. Our simulations show that the binding pocket formed by the two rigid BLPhen ligands allows ample space for two nitrates to bind to the Nd(III) center from opposite sides. Our findings of two nitrates in the first solvation shell of the 2:1 complex and the corresponding bond distances agree well with the available crystal structure. This study represents the first accurate FPMD modeling of the BLPhen–Nd(III) complexes in an explicit organic solvent and opens the door to more atomistic understanding of REE separations from first principles.

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“…The large ionic radii of Ln(III, IV) and U(III) are also expected to be able to form such a 12-coordinate PBU in MOFs considering the presence of 12-coordinate homoleptic Ln dicyanonitrosomethanide (Ln = La−Nd, Sm) ionic liquids 33 or heteroleptic lanthanum phenanthroline-diamide complexes. 34 However, it turns out that Ln(III, IV) assemble into an eight-or nine-coordinate Ln-ADC dimer (Figure S12), while U(III) forms a framework (Figure S13a, Figure S16) near identical to U(IV)-ADC, implying that a majority of U(III) is in situ oxidized to U(IV) likely due to the high reactivity of U(III). 35 Further identification of the oxidation kinetics of the U(III) precursor would be needed to pinpoint the synthetic variables that would lead to the formation of 12coordinate trivalent transuranic MOFs.…”

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confidence: 99%

MOFs with 12-Coordinate 5f-Block Metal Centers

Urbank

Patzschke

et al. 2022

J. Am. Chem. Soc.

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We have constructed an unprecedented MOF platform that accommodates a range of 5f-block metal ions (Th 4+ , U 4+ , Np 4+ , Pu 4+ ) as the primary building block. The isoreticular actinide metal−organic frameworks (An-MOFs) exhibit periodic trends in the 12-coordinate metal environment, ligand configuration, and resulting ultramicroporosity. It holds potential in distinguishing neighboring tetravalent actinides. The metal ionic radius, carboxylate bite angle, anthracene plane twisting, interligand interactions, and countercation templating collectively determine an interplay between solvation, modulation, and complexation, resulting in a coordination saturation of the central actinide, while lanthanide counterparts are stabilized by the formation of a dimer-based motif. Quantum chemical calculations indicate that this large coordination number is only feasible in the high-symmetry environment provided by the An-MOFs. This category of MOFs not only demonstrates autoluminescence (4.16 × 10 4 counts per second per gram) but also portends a wide-bandgap (2.84 eV) semiconducting property with implications for a multitude of applications such as hard radiation detection.

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Strong Periodic Tendency of Trivalent Lanthanides Coordinated with a Phenanthroline-Based Ligand: Cascade Countercurrent Extraction, Spectroscopy, and Crystallography

Cited by 31 publications

References 64 publications

Luminescent Complexes of Europium (III) with 2-(Phenylethynyl)-1,10-phenanthroline: The Role of the Counterions

Luminescent Complexes of Europium (III) with 2-(Phenylethynyl)-1,10-phenanthroline: The Role of the Counterions

Atomistic Insights into Structure and Dynamics of Neodymium(III) Complexation with a Bis-lactam Phenanthroline Ligand in the Organic Phase

MOFs with 12-Coordinate 5f-Block Metal Centers

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