High-Frequency and -Field Electron Paramagnetic Resonance Spectroscopic Analysis of Metal–Ligand Covalency in a 4f7 Valence Series (Eu2+, Gd3+, and Tb4+)

Gompa, Thaige P.; Greer, Samuel M.; Rice, Natalie; Jiang, Ningxin; Telser, Joshua; Ozarowski, Andrew; Stein, Benjamin W.; Pierre, Henry S. La

doi:10.1021/acs.inorgchem.1c01062

Cited by 21 publications

(20 citation statements)

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“…While participation of 5d-orbitals in bonding may be sufficient to understand lanthanides in low oxidation states, there is growing evidence that 4f-orbitals are not fully core-like in tetravalent complexes. ,− ,,− X-ray absorption spectroscopy demonstrates that while 5d-orbital participation is similar in Ce III Cl 6 3– and Ce IV Cl 6 2– , oxidation of Ce III to Ce IV enhances 4f participation to a level comparable to 5d involvement . It has also been shown that lanthanide imidophosphorane complexes show increased covalency via 4f-orbital mixing for higher oxidation states with isoelectronic 4f 7 configurations, such as Tb IV more covalent than Eu II , while isovalent lanthanides show decreasing covalency with increasing atomic number, such as Ce IV more covalent than Tb IV . , …”

Section: Results and Discussionmentioning

confidence: 99%

“…20 It has also been shown that lanthanide imidophosphorane complexes show increased covalency via 4f-orbital mixing for higher oxidation states with isoelectronic 4f 7 configurations, such as Tb IV more covalent than Eu II , while isovalent lanthanides show decreasing covalency with increasing atomic number, such as Ce IV more covalent than Tb IV . 23,28 Covalency via overlap of orbitals is known to contribute to bond stabilization. 19 Minasian and co-workers found enhanced participation of 4f-orbitals in complexes of PrO 2 versus TbO 2 , which was attributed to more diffuse 4f-orbitals of Pr.…”

Section: ■ Concepts and Methodsmentioning

confidence: 99%

“…Significant progress has been made toward synthesizing complexes featuring lanthanide–ligand multiple bonds to terminal carbene, imido, and oxo groups. − Tetravalent lanthanides, Ln IV , are a suitable target for multiple bonding because this relatively high oxidation state lowers the lanthanide orbital energies and facilitates a better energy match with ligand orbitals. − While Ce IV complexes have a comparatively long history, the first reports of isolable complexes featuring Pr IV and Tb IV emerged only in 2019. − To date, no molecular complexes of Pr IV and Tb IV featuring metal–ligand multiple bonds have been isolated.…”

Section: Introductionmentioning

confidence: 99%

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Lanthanide Complexes Containing a Terminal Ln═O Oxo Bond: Revealing Higher Stability of Tetravalent Praseodymium versus Terbium

Shafi

Gibson

2022

Inorg. Chem.

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We report on the reactivity of gas-phase lanthanide-oxide nitrate complexes, [Ln(O)(NO 3 ) 3 ] − (denoted LnO 2+ ), produced via elimination of NO 2• from trivalent [Ln III (NO 3 ) 4 ] − (Ln = Ce, Pr, Nd, Sm, Tb, Dy). These complexes feature a Ln III −O • oxyl, a Ln IV O oxo, or an intermediate Ln III/IV oxyl/oxo bond, depending on the accessibility of the tetravalent Ln IV state. Hydrogen atom abstraction reactivity of the LnO 2+ complexes to form unambiguously trivalent [Ln III (OH)(NO 3 ) 3 ] − reveals the nature of the oxide bond. The result of slower reactivity of PrO 2+ versus TbO 2+ is considered to indicate higher stability of the tetravalent praseodymium−oxo, Pr IV O, versus Tb IV  O. This is the first report of Pr IV as more stable than Tb IV , which is discussed with respect to ionization potentials, standard electrode potentials, atomic promotion energies, and oxo bond covalency via 4fand/or 5d-orbital participation.

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Section: Results and Discussionmentioning

confidence: 99%

Section: ■ Concepts and Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Lanthanide Complexes Containing a Terminal Ln═O Oxo Bond: Revealing Higher Stability of Tetravalent Praseodymium versus Terbium

Shafi

Gibson

2022

Inorg. Chem.

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“…Among the 14 lanthanide elements (Ce–Lu), until recently, the tetravalent oxidation state was readily accessible only for cerium while Pr( iv ), Nd( iv ), Dy( iv ) and Tb( iv ) had only been detected in solid inorganic compounds, double fluorides, oxides, perovskites, 1 or in concentrated aqueous carbonate solutions. 2 Seminal attempts by various groups to isolate molecular complexes of Tb( iv ) and Pr( iv ) were unsuccessful, 3 and only recently Pr( iv ) 4 and Tb( iv ) 5 complexes were finally successfully isolated in organic solvents by taking advantage of the tuning of the +III/+IV oxidation potential by ligand field effects and by a careful choice of the chemical oxidizing agents. These landmark results open a whole new field in lanthanide coordination chemistry and related photonic and magnetic applications.…”

Section: Introductionmentioning

confidence: 99%

Structure, reactivity and luminescence studies of triphenylsiloxide complexes of tetravalent lanthanides

et al. 2022

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“…Assessing the nature of bonding as ionic versus covalent is a central issue in chemistry. , For f-block elements, there is particular interest in the participation of the lanthanide (Ln) 4f and actinide (An) 5f quasi-valence orbitals in both ionic and covalent bonding. − Spectroscopic techniques such as X-ray absorption reveal the characteristics of f-element bonding, often toward understanding and tuning properties. − The nature of bonding also determines the thermodynamic properties of molecules, specifically the bond dissociation energy (BDE). For neutral and cationic lanthanide halides, LnX and LnX + , together denoted as LnX 0,+ (X = F, Cl, Br, I), comparable bonding for different lanthanides with a given halide results in similar bond characteristics such as interatomic distances and vibrational frequencies. , In general, diatomics containing related d-block transition metals , or f-block lanthanides exhibit similar properties that indicate common bond character, whereas their BDEs may vary widely. , Among inherently similar LnF, for example, there are large differences among BDEs, such as 486 kJ/mol for YbF versus 623 kJ/mol for LuF .…”

Section: Introductionmentioning

confidence: 99%

Bond Dissociation Energies Reveal the Participation of d Electrons in f-Element Halide Bonding

Gibson

2022

J. Phys. Chem. A

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Bond dissociation energies (BDEs) reported in the literature for lanthanide monofluorides and lanthanide monochlorides LnX, where X = F or Cl, exhibit substantial irregular variations across the Ln series. It is demonstrated here that correlations of these variations with reported experimentally based atomic energies to prepare the Ln constituent for bonding reveal the nature of the bonding. Whereas some molecular characteristics are well understood in the context of highly ionic bonding, with LnX considered to be (Ln + )(X − ), some significant variations in BDEs are not well rationalized simply by ionization to convert Ln to Ln + for bonding. Focusing here on lanthanide monofluorides LnF, a consideration of alternative Ln preparation schemes shows that a particularly good rationalization of BDEs is obtained by invoking the participation of a lanthanide 5d electron in bonding. This 5d participation could be in ionic (Ln + )(F − ) via π-donation from F − 2p to empty Ln + 5d orbitals or in covalent πbonded Ln:F via polarization from Ln 5d to F 2p, with these ionic and polar covalent perspectives ultimately being equivalent. The inference of lanthanide 5d involvement suggests that the valence 4f and 6s electrons do not effectively participate in some key aspects of the bonding, presumably due to poor spatial overlap with F 2p orbitals. An extension to actinide monofluorides, AnF, assumes analogous ionic or polar covalent bonding involving a valence 6d electron and results in predictions for BDEs that include a general decrease from left to right across the series, except for a distinctive local minimum at AmF. Determining the BDE for AmF would serve to evaluate the predictions and the underlying assumption of 6d bonding. The BDE assessments/predictions for neutral monofluorides, LnF and AnF, are also applied to cationic LnF + and AnF + , and it is noted that the approach can be directly extended to f-element monochlorides, monobromides, and monoiodides.

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High-Frequency and -Field Electron Paramagnetic Resonance Spectroscopic Analysis of Metal–Ligand Covalency in a 4f⁷ Valence Series (Eu²⁺, Gd³⁺, and Tb⁴⁺)

Cited by 21 publications

References 91 publications

Lanthanide Complexes Containing a Terminal Ln═O Oxo Bond: Revealing Higher Stability of Tetravalent Praseodymium versus Terbium

Lanthanide Complexes Containing a Terminal Ln═O Oxo Bond: Revealing Higher Stability of Tetravalent Praseodymium versus Terbium

Structure, reactivity and luminescence studies of triphenylsiloxide complexes of tetravalent lanthanides

Bond Dissociation Energies Reveal the Participation of d Electrons in f-Element Halide Bonding

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