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Scholarly Works (11 results)

  • Thesis
  • Peer Reviewed
UCLA Electronic Theses and Dissertations (2013)

Rare-earths are a group of metals with fascinating physical properties and intriguing chemical reactivity. Organometallic rare-earth chemistry is of particular interest because of the increasing number of their applications in industry and consumer goods as well as the importance of understanding their physical and chemical properties. Despite the dominance of the trivalent oxidation state, recently, low-valent organometallic rare-earth compounds were characterized and showed interesting reactivity toward various molecules. The theme of this thesis is the reduction chemistry of rare-earth metal complexes. By utilizing an electronically and geometrically flexible ferrocene diamide ligand (NNTBS = fc(NSitBuMe2)2, fc =1,1’-ferrocenediyl), unprecedented reactivity was discovered together with the synthesis and characterization of a series of rare-earth metal arene complexes. The fruitful reduction chemistry allowed: (1) the discovery of a new aromatic C-H and C-F bond activation mechanism for rare-earths; (2) the synthesis of the first scandium naphthalene complex and a reactivity study on P4 activation by rare-earth arene complexes; (3) the isolation and characterization of a 6C, 10π-electron aromatic system stabilized by coordination to rare-earth metal ions. Recently, an improved method to access paramagnetic rare-earth starting materials for organometallic chemistry was developed in order to study the physical and chemical properties of paramagnetic rare-earth biphenyl complexes.

    Cover page: Reduction Chemistry of Rare-Earth Metal Complexes: Toward New Reactivity and Properties
    • Article
    • Peer Reviewed
    UCLA Previously Published Works (2015)
    Rare-earth metal complexes of reduced π ligands are reviewed with an emphasis on their electronic structure and bonding interactions. This perspective discusses reduced carbocyclic and acyclic π ligands; in certain categories, when no example of a rare-earth metal complex is available, a closely related actinide analogue is discussed. In general, rare-earth metals have a lower tendency to form covalent interactions with π ligands compared to actinides, mainly uranium. Despite predominant ionic interactions in rare-earth chemistry, covalent bonds can be formed with reduced carbocyclic ligands, especially multiply reduced arenes.
      Cover page: Rare-earth metal π-complexes of reduced arenes, alkenes, and alkynes: bonding, electronic structure, and comparison with actinides and other electropositive metals
      • Article
      • Peer Reviewed
      UCLA Previously Published Works (2017)
        Cover page: Aromatic C–F Bond Activation by Rare-Earth-Metal Complexes
        • Article
        • Peer Reviewed
        UCLA Previously Published Works (2013)
        Two rare-earth (La and Lu) naphthalene complexes supported by a ferrocene diamide ligand activate P4 under ambient conditions to form M 3P7 species exclusively. The resulting complexes feature a Zintl-type polyphosphide P73- unit stabilized by three lanthanide fragments. The reported metal complexes were characterized by X-ray crystallography, multinuclear NMR spectroscopy, and elemental analysis. © 2013 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.
          Cover page: P4 Activation by Lanthanum and Lutetium Naphthalene Complexes Supported by a Ferrocene Diamide Ligand
          • Article
          • Peer Reviewed
          UCLA Previously Published Works (2015)
          © 2015 Elsevier Inc. This review discusses C. H bond activation of hydrocarbons mediated by rare-earth metal complexes with an emphasis on type of mechanisms. The review is organized as follows: in the first part, C. H bond activations mediated by rare-earth metals and actinides following traditional reaction pathways, such as σ-bond metathesis and 1,2-addition, are summarized; in the second part, nontraditional C. H bond activation examples are discussed in detail in order to understand the underlying mechanisms. The scope of the review is limited to rare-earth metals and actinides, but, in some cases, closely related reactivity of group 4 metals will be included for comparison. The purpose of the review is not only to provide a brief overview of C. H bond activation by f-elements but also to bring to attention unusual C. H bond cleavage reactivity following mechanisms different than σ-bond metathesis and 1,2-addition.
            Cover page: C-H Bond Activation of Hydrocarbons Mediated by Rare-Earth Metals and Actinides: Beyond sigma-Bond Metathesis and 1,2-Addition
            • Article
            • Peer Reviewed
            UCLA Previously Published Works (2016)
            Our group has focused on the organometallic chemistry of rare-earth metals and actinides for a decade. By installing ferrocenediamide ligands at electropositive metal centers, we have been able to disclose unprecedented reactivity toward aromatic N-heterocycles, arenes, and other small molecules such as P4. Systematic studies employing X-ray crystallography, spectroscopy, cyclic voltammetry, and density functional theory calculations revealed that the ferrocene backbone could stabilize the electron-deficient metal through a donor-acceptor-type interaction. Most noteworthy is that this interaction can be readily turned on or off by the addition or removal of a Lewis base. In addition to its flexible coordination, the redox-active nature of the ferrocene backbone enabled us to explore redox-switchable transformations. The introduction of ferrocene-based ligands into organolanthanide chemistry not only helped us to study intriguing fundamental problems but also led to fruitful chemistry including small-molecule activation and controlled copolymerization reactions.
              Cover page: Reactivity and Properties of Metal Complexes Enabled by Flexible and Redox-Active Ligands with a Ferrocene Backbone
              • Article
              • Peer Reviewed
              UCLA Previously Published Works (2015)
              Reliable transformation of low-cost rare-earth metal oxides to organometallic rare-earth metal complexes is a prerequisite for the advancement of non-aqueous rare-earth metal chemistry. We have recently developed an in situ method to prepare rare-earth alkyl and halide precursors supported by a diamidoferrocene NNTBS, 1,1′-fc(NSiMe2tBu)2, as an ancillary ligand. Herein, we extended the scope of this method to other lanthanide ions including those that are redox active, such as cerium, praseodymium, samarium, terbium, thulium, and ytterbium. Specifically, samarium trisbenzyl could be generated in situ and then converted to the corresponding samarium benzyl or iodide complexes in good yield. However, it was found that ytterbium trisbenzyl could not be formed cleanly and the consequent conversion to ytterbium iodide complex was low yielding. By adapting an alternative route, the desired ytterbium chloride precursor could be obtained in good yield and purity.
                Cover page: In situ synthesis of lanthanide complexes supported by a ferrocene diamide ligand: extension to redox-active lanthanide ions
                • Article
                • Peer Reviewed
                UCLA Previously Published Works (2014)
                Group 3 metal (E)-stilbene complexes supported by a ferrocene diamide ligand were synthesized and characterized. Reactivity studies showed that they behave similar to analogous naphthalene complexes. Experimental and computational results indicated that the double bond was reduced and not a phenyl ring, in contrast to a previously reported uranium (E)-stilbene complex.
                  Cover page: Group 3 metal stilbene complexes: synthesis, reactivity, and electronic structure studies
                  • Article
                  • Peer Reviewed
                  UCLA Previously Published Works (2014)
                  A new type of C-H bond activation mediated by rare-earth metals under reducing conditions is reported. The synergy between reductants and rare-earth-metal complexes allows the cleavage of unactivated aromatic C-H bonds. The reaction between rare-earth-metal iodides supported by a 1,1'-ferrocenediamide ligand and potassium graphite in benzene leads to the formation of a 1:1 metal molar ratio of the corresponding metal hydride and metal phenyl complex. A proposed mechanism involving an inverse sandwich arene bimetallic intermediate is supported by experimental and computational studies.
                    Cover page: Bimetallic Cleavage of Aromatic C–H Bonds by Rare-Earth-Metal Complexes
                    • Article
                    • Peer Reviewed
                    UCLA Previously Published Works (2015)
                    Inverse sandwich biphenyl complexes [(NN(TBS))Ln]2(μ-biphenyl)[K(solvent)]2 [NN(TBS) = 1,1'-fc(NSi(t)BuMe2)2; Ln = Gd, Dy, Er; solvent = Et2O, toluene; 18-crown-6], containing a quadruply reduced biphenyl ligand, were synthesized and their magnetic properties measured. One of the dysprosium biphenyl complexes was found to exhibit antiferromagnetic coupling and single-molecule-magnet behavior with Ueff of 34 K under zero applied field. The solvent coordinated to potassium affected drastically the nature of the magnetic interaction, with the other dysprosium complex showing ferromagnetic coupling. Ab initio calculations were performed to understand the nature of magnetic coupling between the two lanthanide ions bridged by the anionic arene ligand and the origin of single-molecule-magnet behavior.
                      Cover page: Tetraanionic Biphenyl Lanthanide Complexes as Single-Molecule MagnetsCreative Commons 'BY-ND' version 4.0 license
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