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Synthesis and Reactions of Iron and Ruthenium Dinitrogen ComplexesGuest, Ruth Winifred January 2008 (has links)
Doctor of Philosophy (PhD) / This thesis is primarily concerned with the synthesis and reactions of iron and ruthenium dinitrogen complexes of tripodal phosphine ligands. Of particular interest is the cationic dinitrogen bridged iron complex [(FeH(PP3))2(μ-N2)]2+ 23, containing the tetradentate ligand P(CH2CH2PMe2)3, PP3 1, and its potential for facilitating the reduction of the bound dinitrogen upon treatment with acid. The synthesis of a selection of novel and known tripodal phosphine and amino phosphine ligands is described. New ligands N(CH2CH2CH2PMe2)3 N3P3 7 and P(CH2CH2CH2PiPr2)3 P3Pi3 11 were synthesised by nucleophilic displacement of bromide from the bromoalkylphosphine and bromoalkylamine precursors with the relevant phosphide. A new method for synthesis of known ligand P(CH2CH2CH2PMe2)3 P3P3 19 by the nucleophilic substitution of its chloroalkylphosphine oxide with dimethylphosphide and subsequent reduction is also reported. The reaction of [(FeH(PP3))2(μ-N2)]2+ 23 with base produced the singly deprotonated mixed valence species [(FeH(PP3))(μ-N2)(Fe(PP3))]+ 37 and subsequently the iron(0) dinuclear species (Fe(PP3))2(μ-N2) 38 and mononuclear complex Fe(N2)(PP3) 44. The 15N labelling of complexes has allowed the 15N NMR spectra of 23, 37 and 44 to be reported along with the observation of a long-range 5JP-P coupling across the bridging dinitrogen of 37. Complexes 23 and 37 were also structurally characterised by X-ray crystallography. The treatment of a variety of iron PP3 1 dinitrogen complexes, including the mononuclear species [(Fe(N2)H(PP3)]+ 22, with acid, or base then acid, did not result in the formation of ammonia from reduction of the complexed dinitrogen. The reactions of FeCl2(PP3) 24 and FeClH(PP3) 25 with ammonia and hydrazine afforded the complexes [FeCl(N2H4)(PP3)] 48, [FeH(N2H4)(PP3)] 47, [FeCl(NH3)(PP3)] 49 and [FeH(NH3)(PP3)] 46. Complexes 47 and 46 are considered potential intermediates in any reduction of the dinitrogen ligand of 23 to ammonia. Complexes 49 and 46 were also formed from the decomposition of the hydrazine complexes 48 and 47. The 15N NMR shifts, derived from both the 15N labelling of complexes and from 1H-15N 2D NMR experiments at natural abundance are reported. In addition, complex 47 was characterised by X-ray crystallography. The novel ligand P(CH2CH2PiPr2)3 PPi3 12 was used in the successful synthesis of [FeCl(PPi3)]+ 51 and [RuCl(PPi3)]+ 56. Reduction of 51 and 56 with potassium graphite under dinitrogen afforded the complexes Fe(N2)(PPi3) 52 and Ru(N2)(PPi3) 57 respectively. This is the first report of a Ru(0) dinitrogen complex. Treatment of 52 and 57 with lutidinium tetrafluoroborate resulted in protonation and oxidation of the metal centre to afford the hydrido complexes [Fe(N2)H(PPi3)]+ 53 and [Ru(N2)H(PPi3)]+ 58 respectively. 15N labelled analogues of 52, 53, 57 and 58 were achieved by exchange reactions with 15N2 gas, allowing for analysis by 15N NMR spectroscopy. Species 52, 57 and 58 have also been structurally characterised by X-ray crystallography. Treatment of 52 with excess acid in THF afforded both 53 and the dihydrogen complex [Fe(H2)H(PPi3)]+ 54. The mechanism of formation of 54 probably involves the C-H activation of the solvent THF. The complex cation [RuCl(P3Pi3)]+ 65 was synthesised using the novel ligand P3Pi3 11. A polymeric iron(II) complex, [Fe2Cl4(N3P3)2]n 66, of the tridentate ligand N3P3 7 was also synthesised. Characterisation of both 65 and 66 by X-ray crystallography is reported. (FeCl)2(μ-Cl)2(μ-Pi2)2 68, an unusual bridged dimer of the known ligand CH2(PiPr2)2 Pi2 67, and iron(II) and iron(0) tetramers of the PP3 1 ligand, namely [Fe4Cl4(PP3)5]4+ 71 and Fe4(PP3)5 72 were also characterised by X-ray crystallography.
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Studies on transition metal porphines and phthalocyaninesStrickland, Alan Douglas. Gray, Harry B. January 1900 (has links)
Thesis (Masters)--California Institute of Technology, 1971. / Advisor names found in the Acknowledgments pages of the thesis. Title from home page (03/03/2010). Includes bibliographical references.
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Palladium and Ruthenium Catalyzed ReactionsJAKSIC, BRYAN 05 July 2011 (has links)
Part one of this thesis will discuss research which involves the direct comparison of the activity of commonly used precatalysts with the newly synthesized precatalyst, Pd(η5-C5H5)(η3-1-Ph-C3H4), for Sonogashira cross-coupling reactions. Sonogashira reactions are important as they provide a simple method for the formation of substituted alkynes, a commonly found functionality within important organic molecules. These reactions are generally believed to be catalyzed by a Pd(0)L2 species which are generated in situ from a palladium precatalyst and are often co-catalyzed by CuI although use of the latter is undesirable as it induces homocoupling in certain instances. The rate and quantity of active species generated is not known for the commonly used precatalysts and is a potential reason for decreased rates and yields. Norton et al. have recently demonstrated that the newly synthesized, easily handled compound Pd(η5-C5H5)(η3-1-Ph-C3H4) is a superior precatalyst as it generates the active Pd(0)L2 species more quickly than other commonly used palladium precatalysts. Part one of this thesis will discuss research which investigated the efficiencies of precatalysts used for Sonogashira cross-coupling reactions.
Part two of this thesis will discuss research into the syntheses of a novel series of ruthenium complexes and their utilization as ester hydrogenation catalysts. Reduction of esters to the corresponding alcohols is normally carried out using LiAlH4, a stoichiometric type of reaction which produces large amounts of undesirable by-products. Ruthenium-based catalysts are known to hydrogenate a variety of functional groups and many catalytic systems have been developed for the hydrogenation of alkenes, ketones, etc. The recent literature also describes a small number of ruthenium catalyst systems which enable ester hydrogenation to the same types of alcohols produced by LiAlH4 reduction albeit catalytically, a much “greener” type of chemistry. This paper will discuss the syntheses of a series of Ru(acac)2(phosphine)1-2 complexes and their utilization as ester hydrogenation catalysts. / Thesis (Master, Chemistry) -- Queen's University, 2011-06-29 09:28:58.429
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Synthesis and Reactions of Iron and Ruthenium Dinitrogen ComplexesGuest, Ruth Winifred January 2008 (has links)
Doctor of Philosophy (PhD) / This thesis is primarily concerned with the synthesis and reactions of iron and ruthenium dinitrogen complexes of tripodal phosphine ligands. Of particular interest is the cationic dinitrogen bridged iron complex [(FeH(PP3))2(μ-N2)]2+ 23, containing the tetradentate ligand P(CH2CH2PMe2)3, PP3 1, and its potential for facilitating the reduction of the bound dinitrogen upon treatment with acid. The synthesis of a selection of novel and known tripodal phosphine and amino phosphine ligands is described. New ligands N(CH2CH2CH2PMe2)3 N3P3 7 and P(CH2CH2CH2PiPr2)3 P3Pi3 11 were synthesised by nucleophilic displacement of bromide from the bromoalkylphosphine and bromoalkylamine precursors with the relevant phosphide. A new method for synthesis of known ligand P(CH2CH2CH2PMe2)3 P3P3 19 by the nucleophilic substitution of its chloroalkylphosphine oxide with dimethylphosphide and subsequent reduction is also reported. The reaction of [(FeH(PP3))2(μ-N2)]2+ 23 with base produced the singly deprotonated mixed valence species [(FeH(PP3))(μ-N2)(Fe(PP3))]+ 37 and subsequently the iron(0) dinuclear species (Fe(PP3))2(μ-N2) 38 and mononuclear complex Fe(N2)(PP3) 44. The 15N labelling of complexes has allowed the 15N NMR spectra of 23, 37 and 44 to be reported along with the observation of a long-range 5JP-P coupling across the bridging dinitrogen of 37. Complexes 23 and 37 were also structurally characterised by X-ray crystallography. The treatment of a variety of iron PP3 1 dinitrogen complexes, including the mononuclear species [(Fe(N2)H(PP3)]+ 22, with acid, or base then acid, did not result in the formation of ammonia from reduction of the complexed dinitrogen. The reactions of FeCl2(PP3) 24 and FeClH(PP3) 25 with ammonia and hydrazine afforded the complexes [FeCl(N2H4)(PP3)] 48, [FeH(N2H4)(PP3)] 47, [FeCl(NH3)(PP3)] 49 and [FeH(NH3)(PP3)] 46. Complexes 47 and 46 are considered potential intermediates in any reduction of the dinitrogen ligand of 23 to ammonia. Complexes 49 and 46 were also formed from the decomposition of the hydrazine complexes 48 and 47. The 15N NMR shifts, derived from both the 15N labelling of complexes and from 1H-15N 2D NMR experiments at natural abundance are reported. In addition, complex 47 was characterised by X-ray crystallography. The novel ligand P(CH2CH2PiPr2)3 PPi3 12 was used in the successful synthesis of [FeCl(PPi3)]+ 51 and [RuCl(PPi3)]+ 56. Reduction of 51 and 56 with potassium graphite under dinitrogen afforded the complexes Fe(N2)(PPi3) 52 and Ru(N2)(PPi3) 57 respectively. This is the first report of a Ru(0) dinitrogen complex. Treatment of 52 and 57 with lutidinium tetrafluoroborate resulted in protonation and oxidation of the metal centre to afford the hydrido complexes [Fe(N2)H(PPi3)]+ 53 and [Ru(N2)H(PPi3)]+ 58 respectively. 15N labelled analogues of 52, 53, 57 and 58 were achieved by exchange reactions with 15N2 gas, allowing for analysis by 15N NMR spectroscopy. Species 52, 57 and 58 have also been structurally characterised by X-ray crystallography. Treatment of 52 with excess acid in THF afforded both 53 and the dihydrogen complex [Fe(H2)H(PPi3)]+ 54. The mechanism of formation of 54 probably involves the C-H activation of the solvent THF. The complex cation [RuCl(P3Pi3)]+ 65 was synthesised using the novel ligand P3Pi3 11. A polymeric iron(II) complex, [Fe2Cl4(N3P3)2]n 66, of the tridentate ligand N3P3 7 was also synthesised. Characterisation of both 65 and 66 by X-ray crystallography is reported. (FeCl)2(μ-Cl)2(μ-Pi2)2 68, an unusual bridged dimer of the known ligand CH2(PiPr2)2 Pi2 67, and iron(II) and iron(0) tetramers of the PP3 1 ligand, namely [Fe4Cl4(PP3)5]4+ 71 and Fe4(PP3)5 72 were also characterised by X-ray crystallography.
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Expanding the Scope of Available Iron-Based Catalysts for Suzuki-Miyaura Cross-Coupling Reactions Through Ligand Design and Mechanistic Investigation:Tyrol, Chet Chhawang January 2021 (has links)
Thesis advisor: Jeffery A. Byers / This dissertation describes the design and logic that went into the development of Suzuki-Miyaura cross-coupling reactions catalyzed by iron-based complexes. Chapter 1 provides an overview into the field of iron cross-coupling and the comparison to state-of-the art nickel-based systems. A combination of methodology development and mechanistic insight will be discussed. Chapter 2 describes the initial discovery and optimization of a Suzuki-Miyaura cross-coupling reaction between alkyl halides and unactivated arylboronic pinacol esters catalyzed by an iron cyanobis(oxazoline) complex. Chapter 3 discusses the extension of the catalytic system developed in Chapter 2 to an enantioselective reaction to afford chiral 1,1-diarylalkanes. The dissertation concludes with Chapter 4 which describes the development of a C³-C³ Suzuki-Miyaura reaction catalyzed by a β-diketiminate iron complex. Ligand design and mechanistic studies are discussed here to provide insight into the mechanistic intricacies of the reaction and its effect on future reaction development. / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
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The chemistry of dinuclear complexes bridged by heterodifunctional ligandsDuckworth, Timothy John January 1988 (has links)
No description available.
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Some aspects of the chemistry of co-ordinated organic ligandsWaring, T. L. January 1987 (has links)
No description available.
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Electron-transfer reactions of octahedral manganese (I) carbonyl complexesQuarmby, I. C. January 1988 (has links)
No description available.
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Reactivity of iron and ruthenium dihydride complexesWhittlesey, Michael Keith January 1991 (has links)
No description available.
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The chemistry of ansa-bridged derivatives of molybdenum and tungstenSouter, Joanne January 1996 (has links)
No description available.
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