Covalency in Lanthanides. An X-ray Absorption Spectroscopy and Density Functional Theory Study of LnCl6x–(x= 3, 2)

Löble, Matthias W.; Keith, Jason M.; Altman, Alison B.; Stieber, S. Chantal E.; Batista, Enrique R.; Boland, Kevin S.; Conradson, Steven D.; Clark, David L.; Pacheco, Juan Lezama; Kozimor, Stosh A.; Martin, Richard L.; Minasian, Stefan G.; Olson, Angela C.; Scott, Brian L.; Shuh, David K.; Tyliszczak, Tolek; Wilkerson, Marianne P.; Zehnder, Ralph A.

doi:10.1021/ja510067v

Cited by 201 publications

(321 citation statements)

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“…For comparison, a ground state composition of 75% 3d 10 4f 0 and 25% 3d 10 L4f 1 was found previously to model the LMCT energy (3.3 eV) for (Et4N)2CeCl6 as defined by ΔEgs = 2.5 eV, ΔEfs = -1.5 eV, and Tgs = Tfs = 0.70. 57 Hence, the CTM4XAS calculations suggest that there is slightly more 4f 1 character in the ground state of CeLK4 (38%) than in (Et4N)2CeCl6 (25%). The relatively low percentages of 4f 1 character observed for these two compounds suggested that the LMCT configuration has a smaller contribution to the ground state than previously reported for (C8H8)2Ce, based on L3-edge XANES spectroscopy (89%) and multiconfiguration interaction calculations (80%).…”

Section: Resultsmentioning

confidence: 91%

“…7,12,[17][18][19]22,[24][25][26][154][155][156][157] However, the role of final state effects including core-hole induced changes in 4f occupancy, and other physical phenomena, remains controversial and is the subject of a persistent debate. 18,33,[35][36] Figure 8 compares the background-subtracted and normalized Ce L3-edge XANES spectra of CeLK4 and reference compounds CeO2, 158 [Et4N]2[CeCl6], 57 and (C8H8)2Ce. 99 Each of the L3-edges exhibited a double-peak structure that is characteristic of published data for formally Ce 4+ compounds such as CeO2, Ce(SO4)2, and CeF4.…”

Section: Resultsmentioning

confidence: 99%

“…[55][56] Molecular cerium compounds are usually stabilized in the 4+ formal oxidation state by halides 57 and hard, oxygen donor ligands such as alkoxides [58][59][60][61][62][63][64][65][66][67] and acetylacetonates. [68][69] Many "non-classical" tetravalent cerium molecules have also been prepared, including organometallic compounds, [70][71][72] amide, 65,70,[73][74][75][76][77][78] porphyrins [79][80][81][82][83] and a variety of other multidentate N-donor ligands.…”

Section: Introductionmentioning

confidence: 99%

“…96,98 More recently, an in-depth chlorine K-edge X-ray absorption spectroscopy (XAS) and DFT study showed that Cl 3p and Ln 4f covalency was significant in tetravalent CeCl6 2-but virtually nonexistent in the trivalent analog, CeCl6 3-. 57 In spite of this and other notable synthetic progress, 57,72,87,98,[104][105][106] molecular Ce compounds are seldom the subject of emerging methods for physical and theoretical characterization. Molecular solids are promising candidates for further study because they can often be prepared as pure, crystalline compounds, can be designed with high symmetry, and can be modeled as a complete system without requiring periodic boundary conditions or other approximations.…”

Section: Introductionmentioning

confidence: 99%

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A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹

et al. 2016

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Abstract.A tetravalent cerium macrocyclic complex (CeLK4) was prepared with an octadentate terephthalamide ligand comprised of hard catecholate donors, and characterized in the solution state by spectrophotometric titrations and electrochemistry, and in the crystal by X-ray diffraction. The solution state studies showed that L exhibits a remarkably high affinity towards Ce 4+ , with log β110 = 61(2) and ΔG = -348 kJ/mol, compared with log β110 = 32.02(2) for the analogous Pr 3+ complex. In addition, L exhibits an unusual preference for forming CeL 4-relative to formation of the analogous actinide complex, ThL 4-, which has β110 = 53.7(5). The extreme stabilization of tetravalent cerium relative to its trivalent state is also evidenced by the shift of 1.91 V in redox potential of the Ce 3+ /Ce 4+ couple of the complex (measured at -0.454 V vs. SHE). The unprecedented behavior prompted an electronic structure analysis using L3 and M5,4-edge X-ray absorption near-edge structure (XANES) spectroscopies and configuration interaction calculations, which showed that 4f orbital bonding in CeLK4 has partial covalent character owing to ligand-to-metal charge transfer (LMCT) in the ground state. The experimental results are presented in the context of earlier measurements on tetravalent cerium compounds, indicating that the amount LMCT for CeLK4 is similar to that observed for [Et4N]2[CeCl6] and CeO2, and significantly less than that for the organometallic sandwich compound cerocene, (C8H8)2Ce. A simple model to rationalize changes in 4f orbitals for tri-and tetravalent lanthanide and actinide compounds is also provided.

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Section: Resultsmentioning

confidence: 91%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹

et al. 2016

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“…The forces of electrostatic attraction between ions in a compound cause the chemical bonding of ions with the surrounding ions of opposite charge. However, it has been a longstanding mystery concerning 4f electrons of RE elements when evaluating their chemical bonding ability [4][5][6]. Very recently, we discovered that RE elements can form three types of chemical bonding, namely sp hybridization, spd hybridization, and spdf hybridization [7].…”

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confidence: 99%

4f chemistry towards rare earth materials science and engineering

Xue

Sun

2017

Sci. China Technol. Sci.

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The big challenge in rare earth (RE) resource utilization is to effectively manage their balanced use and advanced applications of 17 elements (Sc, Y and La−Lu) [1,2]. As a family, RE materials possess outstanding optical, electronic, and magnetic properties owing to the unique valence electron structure of RE elements, especially the 4f electrons [3]. With increasing demands of modern applications, the development of novel RE materials becomes an unceasing topic. The application window of RE materials is mainly targeted by two aspects, the high-end utilization and balanced utilization of RE resources. In order to add value to RE resources, understanding the nature of RE materials formation and grasping the advanced techniques in RE materials engineering are indispensable.In the formation of RE materials, the chemical bonding between RE elements and ligands determines the local symmetry and crystal structure of the materials. Understanding the chemical bonding nature of RE elements becomes the most important task. The forces of electrostatic attraction between ions in a compound cause the chemical bonding of ions with the surrounding ions of opposite charge. However, it has been a longstanding mystery concerning 4f electrons of RE elements when evaluating their chemical bonding ability [4][5][6]. Very recently, we discovered that RE elements can form three types of chemical bonding, namely sp hybridization, spd hybridization, and spdf hybridization [7]. Furthermore, it is not necessary for all the valence electron orbitals to hybridize for these RE elements. Therefore, the coordination number of a *Corresponding author (email: dongfeng@ciac.ac.cn) central RE atom can have a wide range of values from 2 to 16, which means many infrastructures upon them can be designed by engineering their bonding environment. The relationship between the orbital hybridization set and coordination number of the RE element concerned enables us to easily clarify which orbitals participate in chemical bonding and how these orbitals distribute in the chemical bonding. It is worth noting that 4f electrons are only involved in chemical bonding when the coordination number of the RE element reaches 10 and above. It should be also mentioned that the origin of the 4f chemical bonding is weak interaction with long bond length.The foundation of RE materials science is 4f chemistry, which dictates the chemical reactions towards the development of novel RE materials. The recent advance in 4f chemical bonding [7] will stimulate the development of RE materials science. In 4f chemistry, the formation and breakage of chemical bonding involving 4f electrons occur in chemical reactions. Specially designed chemical reactions can therefore be used to control the formation of different types of chemical bonds (sp hybridization, spd hybridization, and spdf hybridization) in the synthesis of novel RE materials [8].Targeting the high-end utilization of RE resources, the development trend is to decrease the content of RE elements through substitution of oth...

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Coordination of Actinides and the Chemistry Behind Solvent Extraction

Clark

Yang

Shafer

2018

Experimental and Theoretical Approaches to Actinide Chemistry

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Covalency in Lanthanides. An X-ray Absorption Spectroscopy and Density Functional Theory Study of LnCl₆^x–(x= 3, 2)

Cited by 201 publications

References 149 publications

A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹

A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹

4f chemistry towards rare earth materials science and engineering

Coordination of Actinides and the Chemistry Behind Solvent Extraction

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Covalency in Lanthanides. An X-ray Absorption Spectroscopy and Density Functional Theory Study of LnCl6x–(x= 3, 2)

Cited by 201 publications

References 149 publications

A Macrocyclic Chelator That Selectively Binds Ln4+ over Ln3+ by a Factor of 1029

A Macrocyclic Chelator That Selectively Binds Ln4+ over Ln3+ by a Factor of 1029

4f chemistry towards rare earth materials science and engineering

Coordination of Actinides and the Chemistry Behind Solvent Extraction

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Product

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Covalency in Lanthanides. An X-ray Absorption Spectroscopy and Density Functional Theory Study of LnCl₆^x–(x= 3, 2)

A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹

A Macrocyclic Chelator That Selectively Binds Ln⁴⁺ over Ln³⁺ by a Factor of 10²⁹