Applications of N,N'-Disubstituted-1,8-Diaminonaphthalene as a Scaffold to Support Group 13 Compounds, Carbenes and Pd(II) Carbene Complexes

Lee, Sojung

January 2017

This work is mainly concentrated on the development of new versatile ligand based on N,N’-disubstituted-1,8-diaminonaphthalene (1,8-DAN) for main group chemistry. Therefore, our initial efforts were made on the design of new ligand scaffold by using 1,8-DAN. Following that, new ligand family supported by 1,8-DAN was applied as ligands to main group elements (B, Al, In, Ga, and C). Furthermore, six-membered ring carbenes which are derived from the reaction between N,N’-disubstituted-1,8-diaminonaphthalene and carbon are also investigated. In addition, the stable carbenes were implied as a new ligand system for palladium, leading to the formation of metal ligand complexes. Therefore, the synthesis and reactivity of these complexes are also reported. Chapter I gives an explanation on the basic concepts in terms of the ligand designs and reports the reasons why N,N’-disubstituted-1,8-diaminonaphthalene has been chosen as the framework of for these ligands. Chapter II presents the approach to synthesize ligands depending on the substitution. Regarding this, three methods were successfully used: reductive amination, application of acyl halide followed by reduction, and copper catalyzed C-N coupling reactions. Chapter III describes the reactions between the N,N’-disubstituted-1,8-diaminonaphthalene and main group elements B, Al, Ga, and In in 13 group. In this chapter, a variety of mononuclear and dinuclear complexes are investigated and fully characterized. Furthermore, some computational studies are also reported for the comparison with experimental results. Chapter IV deals with new ligand family, carbene, which is derived from N,N’-disubstituted-1,8-diaminonaphthalene. Therefore, not only fundamental concepts for the NHC (N-heterocyclic carbene) are discussed but also synthetic pathways are introduced. Moreover, interesting features of free carbene are presented as well. Chapter V reports the potential of this new carbene ligand family as ligands for transition metal compound, especially, Pd(II) compounds. Several different pathways for synthesizing the desired metal carbene complexes are presented.

Carbene

Perimidine Based Carbene

1,8-DAN

Main Group

Transition Metal

Synthesis, Characterization, and Biological Activity of Silver Carbene Complexes and Their Precursors

Wright, Brian D.

11 December 2012

No description available.

Chemistry

Antimicrobial

Anticancer

Anti-tumor

Silver

NHC

N-heterocyclic Carbene

Carbene

Carbene ligand and complex design directed towards application in synthesis and homogeneous catalysis

Stander-Grobler, Elzet

12 1900

Thesis (PhD (Chemistry and Polymer Science))--Stellenbosch University, 2008. / Alkylated acetonitrile that forms during the synthesis of the sulfonium salt, [(Me3)2(MeS)S][BF4], is involved in the formation of new , -unsaturated Fischer-type carbene complexes from (CO)5M=C(OMe)CH2Li (M = Cr, W). Metal migration observed when the substitution product obtained from the reaction of the anionic carbene complexes (CO)5M=C(NMe2)CºC¯ (M = Cr, W) with Ph3PAu+ was left in solution, was also kinetically and theoretically investigated. 1H NMR and quantum mechanical (at the B3LYP level of theory) data indicated a complicated mechanism. The a,b-unsaturated Fischer-type carbene complex, (CO)5Cr=C(OMe)CH=C(Me)NH(Me), obtained from the reaction of (CO)5M=C(OMe)CH2¯ with alkylated acetonitrile, was transformed into the new remote one-N, six-membered, carbene ligand (rN1HC6) complex, (CO)5Cr=C(CH=C(Me)N(Me)CH=C(nBu). The carbene ligand unprecedentedly preferred the softer Rh(CO)2Cl moiety to the Cr(CO)5 metal fragment and transferred readily. A new series of remote and abnormal square planar compounds [r/a(NHC)(PPh3)2MCl]CF3SO3 (M = Pd or Ni) was prepared by oxidative substitution. The various positions for metal-carbon bond formation on a pyridine ring to furnish various ligand types i.e. C2 for nN1HC6, C3 for aN1HC6 or C4 for rN1HC6 received attention. The ligands were arranged in increasing order of carbene character, aNHC < nNHC < rNHC and trans influence, nN2HC5 ~ aN1HC6 ~ nN1HC6 < rN1HC6. In competitive situations, oxidative substitution occurred selectively at C4 of the pyridine ring rather than at C2 and on the aromatic ring containing the heteroatom (C4), rather than on an annealed aromatic ring (C7). Crystal and molecular structure determinations confirmed the preferred coordination sites. Quantum mechanical calculations (at the RI-BP86/SV level of theory) indicated that the chosen carbene ligand has a much larger influence than the metal on the BDE of the M-Ccarbene bond; the farther away the N-atom is from the carbene carbon, the stronger the bond. In complexes that also contain additional external nitrogen atoms, e.g. trans-chloro(N-methyl-1,2,4- trihydro-2-dimethylaminepyrid-4-ylidene)bis(triphenylphosphine)palladium(II) triflate and transchloro( N-methyl-1,2,4-trihydro-2-dimethylaminepyrid-4-ylidene)bis(triphenylphosphine)nickel(II) triflate, stabilisation originates from both the nitrogens. 2-Chloro-1-methyl-1H-pyrid-4-ylidenephenylammonium triflate afforded complexes with both remote as well as normal nitrogen atoms. New azole complexes of palladium and nickel with remote heteroatoms were also prepared from N-methyl-4',4'-dimethyl-2'-thiophen-3-chloro-2-yl-4,5-dihydro-oxazole. Employing the compound 1,5-dichloroanthraquinone, the product of a double oxidative substitution on two Pd centra could be isolated but not alkylated. The fact that the chemical shift of the metal bonded carbon in the 13C NMR spectrum can not be used as absolute measure of carbene character, was emphasised in a compound where the heteroatom was situated seven bonds away from the carbon donor. In efforts to synthesise a sulphur-bridged complex that contains carbene ligands, crystals of transdi- iodobis(1,3-dimethyl-imidazoline-2-ylidene)palladium were obtained. Bridged thiolato complexes with N1HC6 ligands were unexpectedly found in the attempt to substitute the halogen on chosen square planar carbene complexes of palladium, widening the application possibilities of N1HC6 ligands in organometallic chemistry beyond that of catalysis. A trinuclear cluster, [(PdPPh3)3(μ-SMe)3]BF4 was isolated as a by-product of these reactions. A series normal and abnormal thiazolylidene complexes of nickel and palladium were prepared by oxidative substitution of the respective 2-, 4- and 5-bromothiazolium salts with M(PPh3)4 (M = Pd or Ni), and unequivocally characterised. In a preliminary catalytic investigation, all the thiazolinium and simple pyridinium derived palladium complexes showed activity in the Suzuki-Miyaura coupling reaction. Little variation in activity in the order a (N next to carbon donor) > n > a (S next to carbon donor) was found for the former series, whereas decreased activity was exhibited in the sequence r > a > n of the latter group. The pyridinium derived complexes showed superior activity to the thiazolinium ones. The rNHC complex, trans-chloro(N-methyl-1,2,4-trihydro-2- dimethylaminepyrid-4-ylidene)bis(triphenylphosphine)palladium(II) triflate, showed similar Suzuki-Miyaura activity to the standard N2HC5 carbene complex precatalyst, trans-chloro[(1,3- dimethyl-imidazol-2-ylidene)triphenylphosphine]palladium(II) triflate.

Carbene complexes

N-heterocylic carbene

Fischer-type carbene

Catalysis

Carbenes (Methylene compounds)

Complex compounds

Transition metal complexes

Heterocyclic compounds

Dissertations -- Chemistry

Theses -- Chemistry

Novel N-heterocyclic carbene architectures for the synthesis and application of structurally dynamic materials

Williams, Kyle Aronson, 1983-

07 October 2010

The recent development of materials with autonomous repair capabilities has opened an exciting new field of polymer science expected to impact nearly every facet of modern society. Similar to natural systems, these "self-healing" materials sense when their structural integrity has been compromised (e.g., due to wear or damage) and respond with a viable repair mechanism. Despite the extraordinary number of successes and advances in this area, a means to ascertain instantaneous knowledge of a material's structural integrity, and more importantly, when it has been compromised, remains a considerable challenge in current systems and materials. To address this challenge, we report recent efforts toward the development of an electronically conductive material that is structurally dynamic and responds to various types of external stimuli. In particular, we have developed new synthetic methodology to prepare a variety of organometallic polymers containing a novel benzobisimidazolylidene or bis(benzoimidazolylidene) ligand, which is comprised of two linearly opposed N-heterocyclic carbenes (NHCs) annulated to a common linker, and various types of transition metals in the polymer's main-chain. Using this approach, polymers with molecular weights up to 10⁶ Da were prepared and cast into robust thin films. Using four-point probe technique, the inherent conductivities of these materials were found to be on the order of 10⁻³ S/cm. Secondly, the dynamics of these polymers were probed in solution using gel permeation chromatography. At specific cross-linker loadings, thermally-responsive gels were obtained. Collectively, these experiments suggested that the essential features for a thermally-responsive, structurally dynamic, conjugated organometallic polymer were developed. Efforts toward probing their ability to display self-healing characteristics in the solid-state are described. The inherent conductivity of the polymers permitted the healing behavior of thin films to be observed by scanning electron microscopy in the absence of a dopant. Long range goals of implementing and utilizing these materials in electronic circuits and other advanced devices are also described. An additional approach towards a dynamic material utilized functional imidazolium-based ionic liquids. A series of functional ionic liquids were produced by appending N-substituents containing pendant halides, alkynes, azides, furans and maleimides. These functional groups allowed for polymerization and crosslinking. The physical properties of the imidazolium monomers, as well as the resulting polymers, could be tuned by altering the anion. When a trifunctional monomer is used in conjunction with the polymerization of difunctional ionic liquids an insoluble crosslinked material forms. This behavior, combined with NHCs ability to bind transition metals as ligands and catalyze various organic transformations, provides potential for this system to be used as a method for catalyst recovery and ultimately catalyst recycling. / text

N-heterocyclic carbene

Dynamic materials

Self-healing

Organometallic polymers

Design, synthesis, and evaluation of new organometallic and polymeric materials for electrochemical applications

Varnado, Charles Daniel, Jr.

24 October 2014

Chemistry / The efforts described in this thesis were bifurcated along two distinct projects, but generally were directed toward the development of new materials to solve outstanding issues in contemporary electrochemical applications. The first project involved the synthesis and application of redox-switchable olefin metathesis catalysts. N-heterocyclic carbenes (NHCs) bearing ferrocene and other redox-active groups were designed, synthesized, and incorporated into model iridium complexes to evaluate their intrinsic electrochemical and steric parameters. Using these complexes, the ability to switch the electron donating ability of the ligands via redox processes was quantified using a variety of electrochemical and spectroscopic techniques. The donicity was either enhanced or attenutated upon reduction or oxidation of the redox-active group, respectively. The magnitude of the change in donicity upon reduction or oxidation did not vary significantly as a function of the proximity of the redox-active group from the metal center. Thus, other factors, including synthetic considerations, sterics, and redox potential requirements, were determined to guide ligand design. Regardless, redox-active NHCs were adapted into ruthenium-based olefin metathesis catalysts and used to gain control control over various ring-opening metathesis polymerizations and ring-closing metathesis reactions. The second project was focused on the development of new basic polymers for acid/base crosslinked proton exchange membranes intended for applications in direct methanol fuel cells. Polymers containing pendant pyridinyl and pyrimidinyl groups were obtained via the post polymerization functionalization of UDEL® poly(sulfone) and then blended with sulfonated poly(ether ether ketone) (SPEEK). Fuel cells containing these blends were found to exhibit reduced methanol crossover, higher open circuit voltages, and higher maximum power densities compared to plain SPEEK. The differences in fuel cell performance were attributed to the basicity and sterics of the pendant N-heterocycles. / text

N-heterocyclic carbene

Ferrocene

Direct methanol fuel cell

Photoionisationsstudien an Radikalen und Carbenen mit VUV-Synchrotronstrahlung / Photoionization Studies on Radicals und Carbenes mit VUV Synchrotron Radiation

Hemberger, Patrick

January 2011

Die vorliegende Dissertation untersucht reaktive Intermediaten, speziell Radikale und Carbene und deren Verhalten bei Photoionisation mit VUV-Synchrotronstrahlung. Diese instabilen Verbindungen wurden durch Pyrolyse von teils selbstsynthetisierter Vorläufern in einem kontinuierlichen Molekularstrahl erzeugt und mittels der TPEPICO-Spektroskopie untersucht. Die wichtigsten Ergebnisse dieser Arbeit werden im Anschluss hervorgehoben. Drei Radikale der Zusammensetzung C9H7, Indenyl, 1- und 3-Phenylpropargyl wurden aus ihren bromierten Vorläufern synthetisiert und ihre Ionisierungsenergien bestimmt. Die Frage ob es möglich ist alle drei Radikale hinsichtlich ihrer IE zu unterscheiden und dadurch eine Identifikation in einer Flamme möglich wird, konnte beantwortet werden. Indenyl und 3-Phenylpropargyl besitzen Ionisierungsenergien von 7.53 und 7.20 eV, was eine Erkennung in Flammen prinzipiell möglich macht. Für 1-Phenylpropargyl wurde eine IEad von 7.4 eV gemessen, was eine selektive Identifikation erschwert. Die Messwerte wurden durch quantenchemischen Rechnungen überprüft und sind mit diesen in guter Übereinstimmung. Die Photoionisation von Cyclopropenyliden (IEad = 9.17 ± 0.015 eV) wurde untersucht,wobei eine niederenergetische Bande dem Propargylen (IEad = 9.02 ± 0.02 eV), dem HCCCH Isomer der Zusammensetzung C3H2, zugeordnet werden konnte. Die Schwingungsstruktur des Spektrums konnte erfolgreich simuliert und dadurch die Geometrie des Kations ermittelt werden. Als Nebenprodukt im Molekularstrahl wurde Chlorcyclopropenyliden (IEad = 9.17 ± 0.02 eV) durch seine Schwingungsprogression identifiziert. Die Analyse der dissoziativen Photoionisation gestaltet sich als schwierig, da sowohl c-C3H2 als auch c-C3HCl im relevanten Energiebereich fragmentieren können und die Anwesenheit von HCl die Auswertung ebenfalls erschwert. Ein Lösungsvorschlag für dieses Problem wurde ebenfalls aufgezeigt. Der Einfluss von Substitutionen auf die IE wurde am Beispiel des Propargylradikals und seiner zwei bromierten Analoga erforscht. Dabei wurde eine Rotverschiebung (IEad(C3H3) = 8.71 ± 0.02 eV / IEad(BrCCCH2) = 8.16 ± 0.02 eV / IEad(BrHCCCH) = 8.34 ± 0.02 eV) gemessen. Diese ist auf den elektronenspendenden Charakter des Broms begründet. Beide Brompropargylradikale lassen sich anhand ihrer IE unterscheiden. Die Schwelle zur dissoziativen Photoionisation von C3H2Br zu C3H2 wurde mit 10.1 eV ermittelt, wobei verschiedene Kanäle für diese Reaktion in Frage kommen. Schwingungsaktivität konnte im TPE-Spektrum des Propargylradikals ebenfalls verzeichnet und die v3 +-Mode mit 1950 cm-1 ermittelt werden. Als letztes Projekt stand die Photoionisation des t-Butyl im Fokus, da teils widersprüchliche Messwerte für die IEad in der Literatur publiziert sind. Es konnte ein Wert von 6.75 eV ± 0.03 eV gemessen werden. Die Schwierigkeit bei diesem Experiment ist die Geometrieänderung während der Ionisierung, da das Radikal pyramidal und das Kation eine planare Struktur im C-Gerüst besitzt. Die Grenzen der angewendeten Methoden wurden an diesem Beispiel deutlich gemacht. Zur vollständigen Charakterisierung wurden auch die Vorläufer genau analysiert, da diese durch dissoziative Photoionisation (DPI) Fragmentionen bilden, welche die gleiche Masse besitzen wie die zu untersuchenden Radikale und Carbene. Aus diesen Ergebnissen konnten Bindungsenergien berechnet werden. Von allen untersuchten reaktiven Intermediaten konnten die Ionisierungsenergien mit einer Genauigkeit von ± 20 meV ermittelt werden. Es wurde gezeigt, dass sogar Isomere mit gleicher Molekülmasse unterscheidbar sind. Diese Daten lassen sich verwenden um reaktive Zwischenprodukte in Flammen zu identifizieren. Die Identifizierung ermöglicht es dann geeignete Modelle für Verbrennungsprozesse zu konstruieren oder vorhandene zu verbessern. Diese könnten wiederum helfen die Ruß- und PAK-Bildung besser zu verstehen. Die Ziele dieser Dissertation konnten somit erreicht werden. Massenspektren, welche in Flammen durch VUV-Synchrotronstrahlung aufgenommen wurden, beherbergen eine große Fülle an größeren reaktiven Intermediaten wie beispielsweise das Fluorenyl oder das Biphenylmethylradikal. Deren Ionisation ist bislang nur sehr vage erforscht und wäre deshalb ein interessantes Projekt um diese Arbeit fortzuführen. / This thesis examines reactive intermediates, especially radicals and carbenes and their behavior at photoionization with VUV-synchrotron radiation. Those unstable compounds were produced by pyrolysis of self-synthesizes precursors in a continuous molecular beam and studied by the TPEPICO spectroscopy. The most important results of this work are highlighted below. Three radicals of the composition C9H7, Indenyl, 1- and 3-phenylpropargyl, were synthesized from brominated precursors and their ionization energies were determined. The question, whether these three radicals can be distinguished by their ionization energy and therefore identified in a combustion flame, was answered. Indenyl and 3-phenylpropargyl exhibit ionization energies of 7.53 and 7.20 eV, which make a distinction possible. For 1-phenylpropargyl an IEad of 7.4 eV was measured, which complicates an selective identification. The measurements were also verified by quantum chemical calculations and are in good agreement. The photoionization of cyclopropenylidene (IEad = 9.17 ± 0.015 eV) was reexamined and and a low-energy band was assigned to propargylene (IEad = 9.02 ± 0.02 eV), which is the HCCCH isomer of the composition C3H2. The vibrational structure of the spectrum of c-C3H2 was successfully simulated and the cationic geometry was also determined. As a by-product chlorocyclopropenylidene (IEad = 9.17 ± 0.015 eV) was found and assigned due to its vibrational progression. The analysis of the dissociative photoionization is difficult, because both c-C3H2 and c-C3HCl are able to fragment in the relevant energy range and the presence of HCl complicates the analysis too. A solution of this problem was also mentioned. The influence of substituents on the IE was studied, using the propargyl radical and its two brominated analogs as an example. A redshift (IEad(C3H3) = 8.71 ± 0.02 eV / IEad(BrCCCH2) = 8.16 ± 0.02 eV / IEad(BrHCCCH) = 8.34 ± 0.02 eV) was measured upon Br substitution. It originates from the electron-donating character of the bromine. Both bromopropargyl radicals can be distinguished by their IE. The threshold of dissociative photoionization of C3H2Br was determined to be 10.1 eV, but several channels can produce the C3H2+ fragment. Vibrational activity was found in the TPE spectrum of the propargyl radical and the v3 + mode was identified (1950 cm-1) as well. As a last project the photoionization of the t-butyl was brought into focus, because partly inconsistent measurements of the IEad are published in the literature. A value of 6.75 ± 0.03 eV was measured in this study. The challenge in experiments on this radical is the huge change in geometry, because the neutral is pyramidal while the cation has a planar carbon framework. The limits of the utilized methods were demonstrated using this example. For a complete characterization the precursors were examined too, because the fragment ions, produced by dissociative photoionization (DPI), could falsely be assigned to the radical or carbene. From these results binding energies were calculated additionally. The ionization energies of all examined reactive intermediates could be determined with an accuracy of ± 20 meV. It was shown that even isomers of the same molecular mass are distinguishable. This data can be used to identify reactive molecules in flames. The identification makes it possible to construct reasonable models for combustion processes or to improve available ones. These models could help to improve the understanding of soot and PAH formation. Therefore the aims of this thesis were achieved. Mass spectra recorded in flames by VUV-synchrotron radiation contain a variety of reactive intermediates for example fluorenyl and biphenylmethyl radicals. Their ionization is only vaguely investigated und therefore an interesting project to continue this work.

Photoionisation

Carbene

Synchrotronstrahlung

Radikal <Chemie>

ddc:540

Copper-Catalyzed Enantioselective Allylic Substitution Reactions with Organoaluminum and Boron Based Reagents Promoted by Chiral Sulfonate Bearing N-Heterocyclic Carbenes

Gao, Fang

January 2013

Thesis advisor: Amir H. Hoveyda / Chapter 1. A Review of Catalytic Enantioselective Allylic Substitution (EAS) with Chiral Sulfonate Containing N-heterocyclic Carbenes (NHC). A comprehensive review of enantioselective allylic substitution reactions, which are promoted by a chiral N-heterocyclic carbene metal complex that features a unique sulfonate motif, is provided in this chapter. Reactions are classified into two categories. One class of transformations is catalyzed by a series of easily modifiable sulfonate bearing NHC-Cu complexes, with which a range of nucleophilic organometallic reagents (i.e., organozinc-, aluminum-, magnesium- and boron-based) that carry different carbon-based units are readily utilized in efficient and highly selective C-C bond forming processes. Another set of reactions exclude the use of a copper salt; catalytic amount of a sulfonate containing imidazolinium salt is capable of promoting additions of alkyl Grignard, zinc and aluminum species to easily available allylic electrophiles in a site- and enantioselective fashion. The mechanistic scenarios of both catalytic systems that account for the observed experimental data are discussed in detail. Chapter 2. Cu-Catalyzed Enantioselective Allylic Substitutions with Aryl- and Heteroarylaluminum Reagents. In this chapter, the first examples of EAS reactions of aryl- and heteroaryl-substituted dialkylaluminum reagents to a wide range of trisubstituted allylic phosphates are demonstrated through a facile and selective catalysis rendered possible by an in situ generated sulfonate containing NHC-Cu complex, delivering enantiomerically enriched olefin products that bear an all carbon quaternary stereogenic center. The requisite organometallic species are easily prepared from either the corresponding aryl- and heteroaryl halides, or through efficient and site selective deprotonation at the C-2 position of furan and thiophene; such aluminum entities are readily used in situ without the requirement of purification. Application to small molecule natural product synthesis is also carried out to illustrate the utility of the present protocol. Chapter 3. Cu-Catalyzed Enantioselective Allylic Substitutions with Alkenylaluminum Reagents. This chapter focuses on our research towards construction of enantioenriched tertiary and quaternary stereogenic centers that are substituted with two further functionalizable alkenes. The first combination of the study involves the addition of stereochemically well-defined trisubstituted alkenylaluminum reagents to disubstituted allylic phosphates; the transformation commences with a silyl-directed stereoselective hydroalumination and finishes with an enantioselective Cu-catalyzed EAS promoted by a sulfonate bearing NHC. Such reactions deliver molecules that feature silicon containing trisubstituted olefin adjacent to the tertiary stereogenic center; subsequent conversion of the versatile silicon group to a proton reveals the first set of examples that incorporate pure Z alkene in Cu-catalyzed EAS. The stereoselective and concise synthesis of naturally occurring small molecule nyasol demonstrates the utility of the above method. On a different front, Ni-catalyzed site-selective hydroalumination of terminal alkynes has opened new possibility of introducing 1,1-disubstituted olefins in Cu-catalyzed EAS in the formation of tertiary stereogenic center containing enantioenriched organic building blocks. Such catalytic hydrometallation procedure also allows efficient access to alkenylaluminums that are derived from the conventionally problematic aromatic alkynes. The importance of efficient and selective synthesis of terminal aryl-substituted alkenylaluminum species is showcased in NHC-Cu-catalyzed EAS reactions that construct all-carbon quaternary stereogenic centers; a three-step convergent synthesis of natural product bakuchiol in enantiomerically enriched form highlights the potential of the current protocol in chemical synthesis. Chapter 4 Cu-Catalyzed Enantioselective Allylic Substitutions with Alkenylboronic Acid Pinacol Ester Reagents and Applications in Natural Product Synthesis. Within this chapter, we disclose the efficient utilization of alkenylboron reagents in Cu-catalyzed EAS reactions, which lead to highly site and enantioselective formations of molecules that contain both tertiary and quaternary carbon stereogenic centers. Unlike their aluminum-based counterparts, the use of boron-based reagents allows effective delivery of sensitive organic function groups, such as a carbonyl, which would be incompatible in the hydrometallation process with dibal-H. Our efforts accumulate to the first report of incorporation of all carbon quaternary centers that are substituted with unsaturated ester and aldehyde units in the EAS products; such a method facilitates the concise diastereo- and enantioselective synthesis of Pummerer's ketone and it's trans isomer. Further development of the above protocol towards the construction of tertiary stereogenic centers requires the design of new chiral sulfonate-containing imidazolinium salts as the ligand precursors and has lead to the employment of a broader range of alkenylboron species, which feature readily functionalizable motifs. Subsequent demonstrations in enantioselective synthesis of a variety of small molecule natural products showcase the utility. / Thesis (PhD) — Boston College, 2013. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Allylic Substitution

Aluminum

Boron

Copper

Enantioselective

N-heterocyclic carbene

New Catalysts and Catalytic Methods for Cycloadditions and Conjugate Additions to Alpha, Beta-Unsaturated Carbonyls

O'Brien, Jeannette M.

January 2012

Thesis advisor: Marc L. Snapper / Chapter 1. A Practical Synthesis of 3-Acyl Cyclobutanones by [2 + 2] Annulation. Mechanism and Utility of the Zn(II)-Catalyzed Condensation of alpha-Chloroenamines with Electron-Deficient Alkenes. We have developed a catalytic method for the synthesis of highly functionalized 3-acyl cyclobutanones which are useful building blocks for a variety of natural products. Methods for cyclobutanone synthesis have traditionally been limited to Lewis-acid promoted rearrangement of oxaspiropentanes or cyclizations of ketene and syntheses involving keteneiminium salts have required stoichiometric quantities of a Lewis acid. Furthermore, the mechanism for these types of cyclizations remains unknown. This portion of my research focused on an efficient, catalytic method for the synthesis of 3- acyl cyclobutanones and providing insight into the mechanism for cycloaddition. Chapter 2. Enantioselective Synthesis of Boron-Substituted Quaternary Carbons by NHC-Cu-Catalyzed Boronate Conjugate Additions to Unsaturated Carboxylic Esters, Ketones, or Thioesters. We have developed an enantioselective NHC-Cu-catalyzed conjugate addition of boronate esters to acyclic, trisubstituted alpha, beta-unsaturated carbonyl compounds. Enantioselective conjugate addition of a boronic acid pinacol ester through the use of bis(pinacolato)diboron [B2(pin)2,] to alpha, beta-unsaturated aliphatic and aryl esters promoted by 5 mol % of an NHC-Cu catalyst afforded tertiary beta-boryl carbonyls in high efficiency and enantioselectivity. Trisubstituted alpha, beta-unsaturated esters and thioesters were found to be reactive substrates in the presence of a stoichiometric quantity of methanol. Chapter 3. Metal-Free Catalytic C-Si Bond Formation in an Aqueous Medium and C-B Bond Formation in a Protic Medium. Enantioselective NHC-Catalyzed Silyl and Boryl Conjugate Additions to Cyclic and Acyclic alpha, beta-Unsaturated carbonyls. We have developed a method for enantioselective metal-free silyl conjugate additions through the use of dimethylphenylsilyl) boronic acid pinacol ester [PhMe2SiB(pin)] catalyzed by chiral N-heterocyclic carbenes (NHCs) in basic aqueous thf. Optimization of metal-free conditions demonstrated that the presence of water was required for high efficiency. alpha, beta-Unsaturated cyclic ketones and lactones were examined as substrates, and acyclic ketones, esters and aldehydes were also competent substrates for silyl conjugate addition. beta-Silyl carbonyls were isolated in up to >98% yield and >98:2 er. Chapter 4. Elucidation of Mechanism for Enantioselective NHC-Catalyzed Silyl Conjugate Addition. We propose a catalytic cycle for NHC-catalyzed enantioselective silyl conjugate addition. Mechanistic studies of NHC-catalyzed enantioselective silyl conjugate additions are presented. Optimization of conditions for an inefficient alpha, beta-unsaturated electron-deficient ketone provided insight into the roles for dbu and water. Kinetic data indicate that conjugate addition is first order in PhMe2SiB(pin) and carbene, and DFT calculations support the formation of an NHC-silyl anion as a reactive intermediate in the catalytic cycle. / Thesis (PhD) — Boston College, 2012. / Discipline: Chemistry.

Boron

Conjugate Addition

Keteneiminium

NHC

N-Heterocyclic Carbene

Silicon

Enantioselective Methods for Allylic Substitution and Conjugate Addition Reactions Catalyzed by N-Heterocyclic Carbene-Copper Complexes

McGrath, Kevin Patrick

January 2016

Thesis advisor: Amir H. Hoveyda / Chapter 1 Catalytic Enantioselective Addition of Organoaluminum Reagents Catalytic methods involving the enantioselective addition of both commercially available as well as in situ generated organoaluminum reagents are reviewed. An overview of additions to aldehydes, ketones, and imines is provided as well as the difficulties and limitations of such transformations. Furthermore, additions to unsaturation adjacent to a leaving group to form a new stereogenic center are examined. Finally, conjugate addition reactions wherein an organoaluminum reagent is added to an olefin adjacent to a carbonyl or nitro group are discussed. Chapter 2 Synthesis of Quaternary Carbon Stereogenic Centers through Enantioselective Cu-Catalyzed Allylic Substitution with Alkenylaluminum Reagents A method for the formation of 1,4-diene containing quaternary stereogenic centers through catalytic enantioselective allylic substitution is disclosed. The addition of alkyl- and aryl-substituted alkenylaluminum reagents to trisubstituted allylic phosphates is promoted by 0.5–2.5 mol % of a sulfonate-containing bidentate N-heterocyclic carbene–copper complex. Products containing a quaternary stereogenic center as well as a newly formed terminal olefin are obtained in up to 97% yield and 99:1 er with high site selectivity (>98:2 SN2’:SN2). The requisite nucleophiles are generated in situ through hydroalumination of terminal alkynes. The utility of the method is demonstrated through a concise synthesis of natural product bakuchiol. Chapter 3 A Multicomponent Ni-, Zr-, Cu-Catalyzed Strategy for Enantioselective Synthesis of Alkenyl-Substituted Quaternary Carbons Despite the widespread use of conjugate addition in organic synthesis, few reports pertain to the addition of nucleophiles to acyclic systems and none in which the nucleophile is an alkene. Herein, we report the first examples of enantioselective conjugate addition of alkenylmetal reagents to trisubstituted enones to form all-carbon quaternary stereogenic centers. Alkenylaluminum nucleophiles are prepared through a site-selective Ni-catalyzed hydroalumination of terminal alkynes and the requisite E-trisubsituted enones are the products of a regioselective Zr-catalyzed carboalumination/acylation of a terminal alkyne. Products are obtained in up to 97% yield and 99:1 er. A model for enantioselectivity, supported by DFT calculations, is proposed. Chapter 4 Formation of Tertiary Centers through Catalytic Enantioselective Conjugate Addition of Alkenylaluminum Reagents to Acyclic Enones We have developed an enantioselective NHC–Cu catalyzed synthesis of tertiary centers in acyclic systems using in situ generated alkenylaluminum reagents, as current methods typically rely on Rh-catalysis at high temperatures with alkenyl boronic acids in protic solvents. Moreover, most examples include chalcone-derived substrates, which, while more reactive, often preclude further functionalization. With the current method, we are able to couple a variety of alkenyl nucleophiles with α,β-unsaturated ketones. E- or Z-silylalkenylaluminum reagents, derived from hydroalumination of silyl-protected alkynes, lead to products in good yields and high enantioselectivities. Additionally, both the α- and β-alkenylaluminum reagents participate in the reaction. Chapter 5 Development of N-Heterocyclic Carbene–Cu Catalyzed Allylic Substitution of Diboryl Methane to Morita-Baylis-Hillman Derived Allylic Phosphates We have developed a method for the coupling of a geminyl diboron reagent with Morita-Baylis-Hillman derived trisubstituted ester-containing allylic phosphates. With 10 mol % of an in situ generated NHC–Cu complex and 1.5 equivalents of the boron reagent, we are able to form the desired product in high regio- and enantioselectivity with a 2,5-ditert-butyl containing carbene. Simple aryl substituents as well as those containing a halogen or an electron-withdrawing group furnish the desired products in up to 85% yield and 98:2 er. Alkyl-containing substrates are also competent reaction partners, although longer chain aliphatics results in slightly diminished enantioselectivity. We are pursuing the application of this method to the synthesis of α-methylene lactones which can be further functionalized to natural products like tubulin polymerization inhibitor (–)-steganone and glaucoma medication (+)-pilocarpine. / Thesis (PhD) — Boston College, 2016. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Allylic Substitution

Conjugate Addition

Copper

Enantioselective

N-Heterocyclic Carbene

Organoaluminum

Intramolecular hydroamination of aminoalkenes with group 2 precatalysts : mechanistic insights and ligand design

Arrowsmith, Merle

January 2011

Long relegated to the background by the pre-eminence of magnesium-based, stoichiometric Grignard reagents, a distinct chemistry of the heavier alkaline earth metals, calcium, strontium and barium, is only now starting to emerge. As similarities have been drawn between the large, electropositive, redox-inert and d0 alkaline earth Ae2+ dications and the Ln3+ cations of the lanthanide series, a growing group 2-mediated catalytic chemistry has developed over the last decade, including polymerisation reactions, heterofunctionalisation reactions of multiple bonds and some rare examples of dehydrocoupling reactions. Among these catalytic reactions the magnesium- and calcium-catalysed intramolecular hydroamination of aminoalkenes has attracted particular interest. Mechanistic studies have demonstrated many parallels with the lanthanide-mediated catalytic cycle based upon successive σ-bond metathesis and insertion steps. In the first part of this thesis, further investigations into the hydroamination/cyclisation reaction have demonstrated the prominent role of the charge density of the catalytic group 2 cation (M = Mg, Ca, Sr, Ba), the beneficial influence of stabilising spectator ligands, and the importance of the choice of the reactive co-ligand for efficient catalyst initiation. Kinetic analyses of reactions monitored by NMR spectroscopy have given new insight into activation energies, entropic effects, substrate and product inhibition, and kinetic isotope effects, leading to a review of the previously suggested lanthanide-mimetic mechanism. In a second part, this study seeks to address two of the main challenges posed by the intramolecular hydroamination reaction in particular, and heavier alkaline earth-catalysed reactions in general: (i) The need to design new monoanionic spectator ligands capable of stabilising heteroleptic heavier alkaline earth complexes and preventing deleterious Schlenk-type ligand redistribution processes in solution; (ii) The stabilisation of highly reactive heteroleptic group 2 alkyl functionalities for fast, irreversible catalyst initiation and novel reactivity.

541.39