Bonding Trends in Molecular Compounds of Lanthanides: The Double‐Bonded Carbene Cations LnCH<sub>2</sub><sup>+</sup> (Ln=Sc, Y, La–Lu)

Roos, Björn O.; Pyykkö, Pekka

doi:10.1002/chem.200902310

Cited by 45 publications

(35 citation statements)

References 32 publications

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“…Such interactions, which are related to the empty valence orbitals on the metal, have been analyzed in detail by Roos, Pyykkç, and co-workers. [9,18] The a-hydrogen interaction was also found to be significant in metal À silicon multiple bonds owing to their electron deficiency. [19] One imaginary frequency, which corresponds to the in-plane twist of the CH 2 group, was found in the C 2v symmetry of all C s (a) MCH 2 + species.…”

Section: Resultsmentioning

confidence: 99%

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Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Zhang

Schwarz

2010

Chemistry A European J

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DFT and CCSD(T) calculations have been performed to investigate the bonding situation of 54 cationic methylene complexes, MCH(2)(+) (M=K-La, Hf-Rn). A comparison of the computed results with experimentally and CBS-QB3-derived data demonstrates the reliability of B3LYP/def2-QZVP with regard to the bond dissociation energies. Further, the bonding character of the MCH(2)(+) complexes is revealed by geometrical and molecular-orbital (MO) analysis. The comparison of the periodic trends within the s-, p-, and d-block MCH(2)(+) carbenes shows a pattern different for main-group versus transition-metal complexes. By combining this work with the recently reported trends for the f-block lanthanide carbenes MCH(2)(+), a systematic and comprehensive overview can be obtained.

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Section: Resultsmentioning

confidence: 99%

“…Lanthanides have been excluded because their carbene complexes have been recently analyzed comprehensively by Roos and Pyykkç. [9] We provide energetic and structural data and, in addition, present a comparison of the periodic trends for the s-, d-, and pelements.…”

Section: Introductionmentioning

confidence: 99%

Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Zhang

Schwarz

2010

Chemistry A European J

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“…The beautiful work of Gagliardi and others about elucidating multiple bonding in late transition metals (e.g. the quintuple bond between two chromium centers), [134][135][136][137][138] lanthanides [139] and actinides (e.g. the quintuple bond in the uranium molecule) [140,141] is a good example of it.…”

Section: Ground-state Description Of Transition Metal Complexesmentioning

confidence: 99%

Progress and Challenges in the Calculation of Electronic Excited States

2011

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A detailed understanding of the properties of electronic excited states and the reaction mechanisms that molecules undergo after light irradiation is a fundamental ingredient for following light-driven natural processes and for designing novel photonic materials. The aim of this review is to present an overview of the ab initio quantum chemical and time-dependent density functional theory methods that can be used to model spectroscopy and photochemistry in molecular systems. The applicability and limitations of the different methods as well as the main frontiers are discussed. To illustrate the progress achieved by excited-state chemistry in the recent years as well as the main challenges facing computational chemistry, three main applications that reflect the authors' experience are addressed: the UV/Vis spectroscopy of organic molecules, the assignment of absorption and emission bands of organometallic complexes, and finally, the obtainment of non-adiabatic photoinduced pathways mediated by conical intersections. In the latter case, special emphasis is put on the photochemistry of DNA. These applications show that the description of electronically excited states is a rewarding but challenging area of research.

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“…[30] Kurz darauf erweiterten Schwarz und Mitarbeiter diese Studien für die gesamte Reihe der MCH 2 + -Kationen (M = K-La und Hf-Rn), um periodische Trends zu identifizieren. [31] Pyykkç et al berechneten, dass prinzipiell alle Lanthanoide Doppelbindungen zur Methylengruppe ausbilden kçnnen.…”

Section: Dft-rechnungenunclassified

“…Die Einfachbindung wird zwischen einem 6s-5d-Hybridorbital und dem s-Radikalorbital am Methylen ausgebildet. [30] Für das Element Cer wurde bei der Berechnung der Schwingungsfrequenzen für das doppelt-gebundene CeCH 2 + -Ion eine imaginäre Frequenz [30] so wie es in den Verbindungen 6, 8 und 10 beobachtet wurde. [18,20,22] Diese Ergebnisse sind im Einklang mit früheren DFT-und Matrix-IR-Studien an Uran-und Thoriummethylidenkomplexen, bei denen ebenfalls eine agostische Wechselwirkung zwischen dem Metallzentrum und einem Wasserstoffatom der Methylidengruppe nachgewiesen werden konnte.…”

Section: Dft-rechnungenunclassified

Methylidenkomplexe der Seltenerdmetalle

Kratsch

Roesky

2013

Angewandte Chemie

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Übergangsmetallcarbene sind bereits seit 50 Jahren bekannt und haben eine breite Anwendung als Reagentien und Katalysatoren in der organischen Synthese gefunden. Die Carbenchemie der Seltenerdmetalle ist dagegen noch recht wenig untersucht und erst in den letzten Jahren in den Fokus der Forschung gerückt. Vor allem Seltenerdmetallalkylidenverbindungen, insbesondere Methylidenkomplexe, sind eine aufstrebende Verbindungsklasse mit einem hohen Potential für die Organometallchemie und möglicherweise künftig für die organische Synthese.

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Bonding Trends in Molecular Compounds of Lanthanides: The Double‐Bonded Carbene Cations LnCH₂⁺ (Ln=Sc, Y, La–Lu)

Cited by 45 publications

References 32 publications

Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Progress and Challenges in the Calculation of Electronic Excited States

Methylidenkomplexe der Seltenerdmetalle

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Bonding Trends in Molecular Compounds of Lanthanides: The Double‐Bonded Carbene Cations LnCH2+ (Ln=Sc, Y, La–Lu)

Cited by 45 publications

References 32 publications

Bonding in Cationic MCH2+ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Bonding in Cationic MCH2+ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Progress and Challenges in the Calculation of Electronic Excited States

Methylidenkomplexe der Seltenerdmetalle

Contact Info

Product

Resources

About

Bonding Trends in Molecular Compounds of Lanthanides: The Double‐Bonded Carbene Cations LnCH₂⁺ (Ln=Sc, Y, La–Lu)

Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends

Bonding in Cationic MCH₂⁺ (M=K–La, Hf–Rn): A Theoretical Study on Periodic Trends