Studies of Metathesis for Materials Applications: Present and Future Possibilities

Marleau-Gillette, Joshua

22 January 2013

Compounds containing multiple metal-carbon bonds are now widely used as catalysts for organic and materials synthesis. Among such transformations, olefin metathesis (OM) occupies a position of pre-eminent significance. Alkyne metathesis holds great promise, but remains in a much lower state of development. The OM-directed work in this thesis sought to advance the state of the art in living, Ru-catalyzed ringopening metathesis polymerizations (ROMP). Currently, the first- and third-generation Grubbs initiators, which exhibit the ease of handling characteristic of the late metal ruthenium, dominate ROMP applications. These initiators are characterized by extremes of reactivity, however. We describe the first ruthenium initiator capable of living ROMP at RT, irrespective of monomer bulk. Polydispersity indices as low as 1.03 are routinely attainable, and excellent control is maintained in synthesis of diblock copolymers from sterically demanding and sterically unencumbered monomers. Work on alkyne metathesis sought to expand existing understanding of the features that influence stability and reactivity in ruthenium carbynes. A classification system was developed in which Class A carbynes were defined as those that readily undergo conversion into an M=C entity (e.g. vinylidene, allenylidene, or alkylidene); Class B carbynes those that have a stable carbyne functionality. Four Ru carbyne complexes, all initially regarded as prospective Class B carbynes, were selected for study. Investigation of their reactivity resulted in categorization of several as Class A species, and development of design criteria that may open the door to assembly of stable, well-defined carbyne complexes of ruthenium.

Olefin Metathesis

Alkyne Metathesis

Ring-opening Metathesis Polymerization

Ruthenium Carbynes

Linear Pseudohalide

New olefin metathesis catalysts with fluorinated NHC ligands : synthesis and catalytic activity / Nouveaux catalyseurs de métathèse des oléfines à ligands carbènes N-hétérocycliques fluorés : synthèse et activité catalytique

Masoud, Salekh

14 December 2017

La préparation efficace d’une nouvelle famille de sels de 1,3-bis(aryl)-4,5-dihydroimidazolium non symétriques comprenant un groupement encombrant hexafluoroisopropylmethoxy en position para- ou ortho- sur l’un des substituants N-aryle a été développée. De nouveaux sels d’imidazolium contenant un substituant fluoroalkyle en position ortho d’un des substituant aryle ont aussi été synthétisés. Ces sels sont d’excellents précurseurs de carbènes N-hétérocycliques qui ont permis l’accès efficace à une série de nouveaux complexes carbéniques du ruthénium à ligands NHC non symétriques. La méthode repose sur la génération in situ du carbène par traitement des sels d’imidazolium avec le potassium hexamethyldisilazide suivie d’un échange du ligand tricyclohexylphosphine à partir des complexes de Grubbs et Hoveyda de première génération. L’activité de ces nouveaux complexes a été étudiée sur des réactions modèles intra- et intermoléculaires de métathèse des oléfines. Il a été montré que la plupart des complexes synthétisés ont de bonnes activités catalytiques en fermeture de cycle à partir du diallylmalonate d’éthyle et en métathèse croisée de l’allylbenzène avec le 1,3-diacetoxybut-2-ene. Leurs performances sont comparables à celles des catalyseurs de Grubbs et Hoveyda de seconde génération, avec toutefois quelques différences dans les étapes d’initiation. Les effets structuraux et électroniques des ligands NHC non symétriques sur la réactivité des nouveaux complexes du ruthénium ont été étudiés. En particulier, il a été montré que les catalyseurs de type Hoveyda porteurs de ligands monosubstitués par un groupement fluoroalkyle en position ortho d’un des substituant N-aryle présentent une initiation très rapide dans les réactions de métathèse croisée. Au contraire, les complexes porteurs d’un groupement donneur alkyle ont montré une activité catalytique très faible, comme par exemple le complexe porteur d’un ligand (tert-butyl)NHC qui s’est révélé inerte à la fois en fermeture de cycle et métathèse croisée. Les complexes porteurs d’un ligand NHC symétrique avec deux groupes hexafluoroisopropylmethoxy ont des activités catalytiques nettement inférieures à leurs homologues non symétriques, révélant ainsi la forte influence de l’absence de symétrie du ligand carbène NHC dans l’activité catalytique des complexes. / An efficient approach to a new family of unsymmetrical 1,3-bis(aryl)-4,5-dihydroimidazolium salts comprising bulky hexafluoroisopropylmethoxy group in para- or ortho-position in one of the N-aryl substituents has been developed. New imidazolinium salts with fluoroalkyl-containing mono-ortho-aryl substituent at one of the nitrogen atom have also been synthesized. It was found that these imidazolinium salts are effective NHC precursors and provided an efficient access to a series of new ruthenium carbene complexes with unsymmetrical fluorinated NHC ligands. The method involves in situ generation of the carbene via treatment of the starting salts with potassium hexamethyldisilazide and subsequent ligand exchange reaction with PCy3-containing first generation Grubbs and Hoveyda complexes. The catalytic activity of the new complexes has been investigated on model reactions of intra- and intermolecular olefin metathesis. It was found that most of the synthesized complexes exhibited high activity in cyclization of diethyl diallylmalonate and in cross metathesis of allyl benzene with 1,3-diacetoxybut-2-ene. Their performance has proved to be comparable with commonly used second generation Grubbs and Hoveyda catalysts, with sometimes some differences in the initiation step. Structural and electronic impact of fluorinated unsymmetrical NHC on reactivity of new ruthenium complexes has been studied. In particular, it was revealed that Hoveyda type catalysts with mono-ortho-aryl substituted NHC ligands have demonstrated very high initiation rate in CM reactions. On the contrary, catalysts with more donating N-alkyl NHCs have displayed low activity; for instance, the N-tert-butyl substituted complex has proved to be absolutely inert both in RCM and CM reactions. Symmetrical ruthenium carbene complexes bearing NHC ligands with two hexafluoroisopropylmethoxy group in para-positions of N-aryl moieties are significantly inferior in reactivity with respect to their asymmetric counterparts showing the strong influence of the desymmetrization factor on catalytic activity.

Carbènes N-Hétérocycliques

Carbènes fluorés

Catalyseurs de métathèse des oléfins

N-Heterocyclic carbenes

Fluorinated carbenes

Olefin metathesis catalysts

Efeitos eletrônicos e estéricos de ligantes ancilares: relação estrutura-reatividade em complexos do tipo [RuCl2(PPh3)x(amina)y] para polimerização de olefinas via metátese / Electronic and steric effects of ancillary ligands: structure-reactivity relationship in [RuCl2(PPh3)x(amine)y] complex types for ring opening metathesis polymerization of olefins

José Luiz Silva Sá

31 August 2011

Os complexos do tipo [RuCl2(PPh3)2amina], amina = pip (1) ou pep (2), foram estudados como iniciadores catalíticos para reações de ROMP de NBE, NBD e oxaNBE-OMe e na ROMCP de NBE com NBD e oxaNBE-OMe com NBE. O complexo [RuCl2(PPh3)(pep)(isn)] (3) foi estudado na ROMP de NBE e NBD. Os complexos 2 e 3 são inéditos e suas caracterizações são discutidas e correlacionadas com o complexo com 1. As reações de catálises foram realizadas com variações de tempo, volume de solvente e temperatura, em atmosfera de Ar ou ar e na presença de EDA. <br />O rendimento foi quantitativo na ROMP de NBE com o complexo 1 em 2 mL de CHCl3, por 5 min a 25 &deg;C em Ar, com IPD de 1,9 e Mw na ordem de 106 g mol-1. Com o complexo 2, os rendimentos foram quantitativos (IPD ~ 3 e Mw na ordem de 104 g mol-1) e independentes do tempo (5 -120 min) e volume de solvente (2 - 8 mL). Com 3, os rendimentos diminuíram com o aumento do volume de solvente, mas com IPD ~ 2 e Mw na ordem de 104 g mol-1. Em todos os casos os rendimentos diminuíram em atmosfera de ar e com polímeros polimodais. <br />Rendimentos quantitativos de poliNBD foram obtidos com 1 a 40 &deg;C e com 2 a 25 &deg;C na faixa de volume de solvente estudada, por 60 e 120 min, em Ar. Os rendimentos com 3 foram inferiores a 35%. Foram também obtidos rendimentos quantitativos em atmosfera de ar em certas combinações de tempo e volume de solvente, indicando que os complexos são robustos para atividades em soluções contendo O2. Todos os polímeros de NBD foram insolúveis. <br />Obteve-se até 70% de poli(NBE-co-NBD) isolado a partir de reações com 1 e reações quantitativas com 2, dependendo da fração molar NBE:NBD usada, indicando as razões de reatividades do complexos. <br />A ROMP de oxaNBE-OMe com 1 ou com 2 formou 15 a 30% de rendimento, a 40 &deg;C por 24 h em Ar. Na ROMCP desse monômero com NBE obteve-se de 5 a 30% de rendimento, dependendo da fração molar. Os rendimentos são maiores nas frações molares com maior quantidade de NBE. Poli(oxaNBE-OMe) foi solúvel, enquanto que seus copolímeros foram pouco solúveis. <br />São realizadas discussões quantos às características eletrônicas e de impedimentos estéricos nos complexos estudados nas polimerizações via metátese, selecionando-se os ligantes ancilares frente às condições de reações para obtenções de bons rendimentos e características dos polímeros isolados. / The complexes of type [RuCl2(PPh3)2amina], amine = pip (1) or pep (2), were studied as catalytic initiators for ROMP of NBE, NBD and oxaNBE-OMe and for ROMCP of NBE with NBD and oxaNBE-OMe with NBE. The complex [RuCl2(PPh3)(pep)(isn)] (3) was studied for ROMP of NBE and NBD. The complexes 2 and 3 are novels and their characterizations are discussed and correlated with the complex 1. The catalysis reactions were performed with variations of time, volume of solvent and temperature, either in Ar or air atmosphere, in the presence of EDA. <br />The yield was quantitative for ROMP of NBE with complex 1 in 2 mL of CHCl3 for 5 min at 25 &deg;C in Ar, with PDI of 1.9 and Mw in the order of 106 g mol-1. With the complex 2, the yields were quantitatives (PDI ~ 3 and Mw in the order of 104 g mol-1) and independent of time (5 - 120 min) and volume of solvent (2 - 8 mL). With 3, the yields decreased when increasing the volume of solvent, but with PDI ~ 2 and Mw in the order of 104 g mol-1. In all the cases, the yields decreased in air atmosphere with polymodal polymers. <br />Quantitative yields of poliNBD were obtained with 1 at 40 &deg;C and with 2 at 25 &deg;C in the range of the studied volume of solvent, for 60 and 120 min, in Ar. The yields with 3 were less than 35%. Quantitative yields were also obtained in air atmosphere in some combinations of time and volume of solvent, indicating that the complexes are robust for activities in solutions containing O2. All polyNBD were insoluble. <br />It was obtained up to 70% of poly(NBE-co-NBD) isolated from reactions with 1 and quantitative reactions were obtained with 2, depending on the NBE:NBD molar fraction used, indicating the reactivity ratios for the complexes. <br />The ROMP of oxaNBE-OMe with 1 or with 2 yielded 15 to 30% at 40 &deg;C for 24h in Ar. In the ROMCP of this monomer with NBE, it was obtained from 5 to 30% yield, depending on the molar fraction. Yields are higher in molar fractions with higher amount of NBE. Poly(oxaNBE-OMe) was soluble, while its copolymers were poorly soluble. <br />Discussions are held on the electronic characteristics and steric hindrances in the studied complexes for the metathesis polymerization, selecting the ancillary ligands as a function of the reaction conditions to obtain good yields and to improve the characteristics of the isolated polymers.

Catálise homogênea

Ligantes ancilares

Metátese de olefinas

Ancillary ligand

Homogeneous catalysis

Olefin metathesis

O efeito do substituinte no anel piperidina na reatividade de pré-catalisadores do tipo [RuCl2(PPh3)2(4-CH2X-pip)] em ROMP / The effect of the substituent in the piperidine ring in the reactivity of [RuCl2(PPh3)2(4-CH2X-pip)] as pre-catalyst for ROMP

Henrique Koch Chaves

10 August 2011

As moléculas de 4-CH2X-piperidinas, X = OH (1), H (2) e Ph (3) foram investigadas como ligantes ancilares nos novos complexos [RuCl2(PPh3)2(4-CH2X-pip)] para a polimerização via metátese por abertura de anel (ROMP) de norborneno (NBE) e norbornadieno (NBD). Os complexos foram obtidos pela síntese com [RuCl2(PPh3)3] e caracterizado por análise elementar de CHN, infravermelho e RMN 31P {1H}. Os resultados sugeriram moléculas pentacoordenadas com ambos os íons cloreto e ambos os ligantes fosfinas trans-posicionados em uma geometria pirâmide de base quadrada em cada caso; a amina está no eixo axial.<br /> ROMP de NBE com 1 foram realizadas em argônio em função do volume de etildiazoacetato (EDA; 2 - 8 &micro;L), razão molar [NBE]/[Ru] (1.000 - 10.000), tempo ( 5 - 60 minutos) e temperatura (25 e 50 &deg;C) para obter a melhor condição de reação. Com 2 &micro;L de EDA a 50 &deg;C por 30 minutos e [NBE]/[Ru] = 5000, poliNBE foi quantitativamente isolado com Mw = 20,6 x 104 e IPD = 2,2. Em condições similares, rendimentos de 80 e 83% foram obtidos com 2 e 3, respectivamente (Mw = 2,4 x 104 e 0,2 x 104; IPD = 2,3 e 1,8). Os rendimentos em presença de PPh3 em excesso (20 equivalentes) foram reduzidos para 18 - 32%, enquanto na presença de amina (20 equivalentes) o complexo foi totalmente inativo. É sugerido que as reações de ROMP ocorrem quando o ligante PPh3 abandona a esfera de coordenação do Ru, e a amina em excesso envenena o catalisador devido à forte coordenação &sigma;. Experimentos com NBE em ar atmosférico resultaram em 68-77% de rendimentos, sugerindo boa resistência dos complexos à oxidação com O2.<br /> Os rendimentos para a ROMP de NBD foram de 100, 54 e 73% para 1, 2 e 3 respectivamente, utilizando as mesmas condições. Os poliNBD foram insolúveis em CHCl3. Poli[NBE-co-NBD] foram obtidos com 57 - 71% de rendimento com cada um dos complexos em presença de diferentes frações molares de comonômeros. / The molecules 4-CH2X-piperidines, X = OH (1), H (2) e Ph (3) were investigated as ancillary ligands in the new [RuCl2(PPh3)2(4-CH2X-pip)] complexes for ring opening metathesis polymerization (ROMP) of norbornene (NBE) and norbornadiene (NBD). The complexes were obtained from syntheses with [RuCl2(PPh3)3] and characterized by CHN elementary analyses, infrared and 31P-NMR. The results suggested penta-coordinated molecules with both chloro and both phosphine ligands trans-positioned in a square pyramid geometry in each case; the amine is the axial axis.<br /> ROMP of NBE with 1 were carried out in argon atmosphere in a function of ethyldiazoacetate volume (EDA; 2 - 8 &micro;L), [NBE]/[Ru] molar ration (1,000 - 5,000), time (5- 60 min) and temperature (25 and 50 &deg;C) to obtain the best reaction conditions. With 2 &micro;L of EDA at 50 &deg;C for 30 min and [NBE]/[Ru] = 5,000, polyNBE was quantitatively isolated with Mw = 20,6 x 104 e IPD = 2,2. In similar conditions, yields of 80 and 83% were obtained with 2 e 3, respectively (Mw = 2,4 x 104 and 0,2 x 104; PDI = 2,3 and 1,8). The yields in presence of PPh3 in excess (20 equivalents) were reduced to 18 - 32%, whereas in presence of amine (20 equivalents) the complexes were totally inactive. It is suggested that the ROMP reactions occurs when a PPh3 ligand leaves the Ru coordination sphere and the amine in excess poison the catalyst due to a strong &sigma;-coordination. Experiments with NBE in atmospheric of air resulted in 68-77% yields, suggesting good O2-resitances of the complexes to oxidation.<br /> The yields for ROMP of NBD were 100, 54 and 73% with 1, 2 e 3, respectively, under the same conditions. The polyNBD were insolubles in CHCl3. Poly[NBE-co-NBD] were obtained with 57 - 71% yield with either one of the complexes in presence of different comonomer molar fractions.

Catálise homogênea

Metátese de olefinas

Polimerização

Rutênio

Homogeneous catalysis

Olefin metathesis

Polimerization

Ruthenium

Influência do ambiente local no desempenho do catalisador de Grubbs / Effluence of the local environment on the activity of Grubbs catalysts

Aragão, Isaias Barbosa, 1990-

25 August 2018

Orientadores: Daniela Zanchet, Regina Buffon / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-25T08:37:31Z (GMT). No. of bitstreams: 1 Aragao_IsaiasBarbosa_M.pdf: 4247291 bytes, checksum: 09937fc60abf375cebc0a59dc22ae39a (MD5) Previous issue date: 2014 / Resumo: Nanopartículas (NPs) e os ligantes em sua superfície vêm ganhando espaço como meio suporte devido a suas propriedades que aliam o comportamento da catálise homogênea com a heterogênea. Em longo prazo, imagina-se que o controle do ambiente local de espécies ancoradas na superfície destas NPs possa mimetizar o sítio catalítico de enzimas. Visando explorar a influência do ambiente local, foi avaliado o desempenho do catalisador de Grubbs de primeira geração em duas condições: encapsulado em matriz de sílica e na presença de NPs de ouro (NPs-Au). Apesar das reações de encapsulamento pelo método sol-gel serem rotas bastante exploradas, os resultados não foram encorajadores devido à desativação do complexo de rutênio nas condições de formação do gel, tanto pela via hidrolítica quanto não-hidrolítica. Com relação às NPs-Au, elas foram sintetizadas com misturas de ligantes (1-octanotiol e ácido 3-mercaptopropiônico), mostrando separação de fases dos ligantes, com a formação de domínios (raias). Nos estudos com catalisador de Grubbs em reações de metátese (autometátese do 1-hexeno e polimerização por abertura de anel do 1,5-ciclooctadieno), tanto a presença das NPs-Au como a de tiol livre tiveram influência negativa, levando a sua desativação prematura. Na presença de NPs-Au, houve queda da atividade, chegando a conversões nulas para razões mássicas maiores de que 1 mg de ouro/10 mg de catalisador, estando possivelmente associado à complexação das mercaptanas das NPs-Au com o complexo de rutênio. Buscando viabilizar o ancoramento do catalisador nas NPs-Au, sintetizou-se um ligante carbeno NHC com a funcionalização do esqueleto carbônico posterior do anel com um grupamento alil, que representa a primeira etapa para introdução de grupos funcionais e ancoramento em NPs / Abstract: The use of nanoparticles (NPs) and their protecting layer as support in catalysis start to be exploited, due to their unique characteristics at the interface of homogeneous and heterogeneous catalysts. At long term, the tuning of the local environment of catalytic species anchored on the surface of NPs may be a way to mimic the active site of enzymes. Aiming to explore the influence of the local environment, we evaluated the activity of the first generation Grubbs catalyst under two conditions: encapsulating it in a silica matrix and in the presence of gold NPs (NPs-Au). Although the heterogenization via the sol-gel method is a well-known and well-explored route, we could not obtain good results due to catalyst deactivation under gel formation in both hydrolytic and non-hydrolytic (nonaqueous) conditions. Considering the NPs-Au, they were synthesized with success using a mixture of ligands (1-octanethiol and 3-mercaptopropionic acid) that showed phase segregation and formation of stripes. The evaluation of the Grubbs catalyst on metathesis reactions (self-metathesis of 1-hexene and ring opening polymerization of 1,5-ciclooctadiene) showed premature deactivation in the presence of both NPs-Au and free thiol. In the presence of NPs-Au, the catalytic activity descreased, achieving null results when weight ratios bigger than 1mg of NPs-Au to 10 mg of catalyst were used, possibly associated to the interaction between the mercaptans and the ruthenium catalyst. To make possible the catalyst anchoring on the NPs-Au surface, a NHC carbene with an allyl group on its carbon backbone was synthesized, corresponding to the first step to introduce functional groups to the catalyst / Mestrado / Quimica Inorganica / Mestre em Química

Nanopartículas de ouro

Nanopartículas raiadas

Metátese de olefinas

Catalisador de Grubbs

Gold nanoparticles

Striped nanoparticles

Olefin metathesis

Grubbs catalyst

New Directions in Catalyst Design and Interrogation: Applications in Dinitrogen Activation and Olefin Metathesis

Blacquiere, Johanna M.

January 2011

A major driving force for development of new catalyst systems is the need for more efficient synthesis of chemical compounds essential to modern life. Catalysts having superior performance offer significant environmental and economic advantages, but their discovery is not trivial. Well-defined, homogeneous catalysts can offer unparalleled understanding of ligand effects, which proves invaluable in directing redesign strategies. This thesis work focuses on the design of ruthenium complexes for applications in dinitrogen activation and olefin metathesis. The complexes developed create new directions in small-molecule activation and asymmetric catalysis by late-metal complexes. Also examined are the dual challenges, ubiquitous in catalysis, of adequate interrogation of catalyst structure and performance. Insight into both is essential to enable correlation of ligand properties with catalyst activity and/or selectivity. Improved methods for accelerated assessment of catalyst performance are described, which expand high-throughput catalyst screening to encompass parallel acquisition of kinetic data. A final aspect focuses on direct examination of metal complexes, both as isolated species, and under catalytic conditions. Applications of charge-transfer MALDI mass spectrometry to structural elucidation in organometallic chemistry is described, and the technique is employed to gain insight into catalyst decomposition pathways under operating conditions.

Olefin Metathesis

Organometallics

Dinitrogen

High-Throughput Experimentation

MALDI Mass Spectrometry

Ruthenium

Catalysis

Studies of Metathesis for Materials Applications: Present and Future Possibilities

Marleau-Gillette, Joshua

January 2013

Compounds containing multiple metal-carbon bonds are now widely used as catalysts for organic and materials synthesis. Among such transformations, olefin metathesis (OM) occupies a position of pre-eminent significance. Alkyne metathesis holds great promise, but remains in a much lower state of development. The OM-directed work in this thesis sought to advance the state of the art in living, Ru-catalyzed ringopening metathesis polymerizations (ROMP). Currently, the first- and third-generation Grubbs initiators, which exhibit the ease of handling characteristic of the late metal ruthenium, dominate ROMP applications. These initiators are characterized by extremes of reactivity, however. We describe the first ruthenium initiator capable of living ROMP at RT, irrespective of monomer bulk. Polydispersity indices as low as 1.03 are routinely attainable, and excellent control is maintained in synthesis of diblock copolymers from sterically demanding and sterically unencumbered monomers. Work on alkyne metathesis sought to expand existing understanding of the features that influence stability and reactivity in ruthenium carbynes. A classification system was developed in which Class A carbynes were defined as those that readily undergo conversion into an M=C entity (e.g. vinylidene, allenylidene, or alkylidene); Class B carbynes those that have a stable carbyne functionality. Four Ru carbyne complexes, all initially regarded as prospective Class B carbynes, were selected for study. Investigation of their reactivity resulted in categorization of several as Class A species, and development of design criteria that may open the door to assembly of stable, well-defined carbyne complexes of ruthenium.

Olefin Metathesis

Alkyne Metathesis

Ring-opening Metathesis Polymerization

Ruthenium Carbynes

Linear Pseudohalide

New Ru-Based Catalysts and Strategies for Kinetically Controlled Stereoselective Olefin Metathesis:

Xu, Chaofan

January 2020

Thesis advisor: Amir H. Hoveyda / Chapter 1. In Situ Methylene Capping: A Key Strategy in Catalytic Stereoretentive Olefin MetathesisA general approach for in situ methylene capping that significantly expands the scope of catalyst-controlled stereoselective olefin metathesis is presented. By incorporation of stereodefined 2-butene as the capping reagent, the catechothiolate Ru complex is enabled to catalyze olefin metathesis reactions of terminal alkenes. Substrates bearing a carboxylic acid, an aldehyde, an aryl substituent, an α substituent were thus converted to the desired products in 47–88% yield and 90:10–98:2 Z:E selectivity. The capping strategy was also applied in ring-closing metathesis reactions leading to 14- to 21-membered macrocyclic alkenes (96:4–98:2 Z:E). The utility of this method was highlighted through synthesis of a platelet aggregate inhibitor and two members of the prostaglandin family compounds by cross-metathesis reaction, as well as a strained 14-membered ring stapled peptide by macrocyclic ring-closing metathesis. Examples of the corresponding E-selective cross-processes are provided as well. Chapter 2. Synthesis of Z- or E-Trisubstituted Allylic Alcohols and Ethers by Kinetically Controlled Catalytic Cross-MetathesisKinetically controlled Ru-catalyzed cross-metathesis reactions that generate Z- or E-trisubstituted alkenes are discussed. Reactions were catalyzed by catechothiolate Ru complex to generate trisubstituted allylic alcohols and ethers in up to 81% yield and >98% stereoisomeric purity. The approach is applicable to synthesis of products containing an alcohol, an aldehyde, a carboxylic acid or an alkenyl substituent. Mechanistic models that account for the observed trends in efficiency and stereoselectivity will be provided. Chapter 3. A New Ru-Based Catechothiolate Complex Bearing an Unsaturated NHC Ligand for Synthesis of Z-α,β-Unsaturated Carbonyl Compounds by Cross Metathesis Design and development of a new Ru catechothiolate complex that may be used to promote Z-selective cross-metathesis transformations that afford Z-α,β-unsaturated esters, acids, and amides (including Weinweb amides) are discussed. Comparison between Ru catechothiolate complexes with an unsaturated NHC and a saturated NHC ligand will be provided. Utility of the approach is demonstrated by an eight-step synthesis (15% overall yield) of an intermediate for synthesis of stagonolide E, and a five-step synthesis of a precursor to dihydrocompactin / Thesis (PhD) — Boston College, 2020. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Cross metathesis

Macrocyclic ring-closing metathesis

Ruthenium

Stereoretentive

Stereoselective olefin metathesis

Functional Metal Organic Frameworks for Surface Organometallic Chemistry and Carbon Conversion

Thiam, Zeynabou

05 1900

Abstract: Metal-Organic Frameworks (MOFs) are a class of highly porous, hybrid, functional and crystalline extended coordination compounds. Their exceptional properties renders them ideal for a wide range of applications including gas storage and catalysis. Especially for catalysis, MOFs are receiving attention as well-defined supports for organometallic heterogeneous catalysis with noticeably the post-synthetic grafting of transition metal complexes on secondary building units (SBU) containing hydroxides moieties. The objective of this dissertation is to explore the synthesis, reactivity and functionalization of MOFs with SBU containing hydroxides units by transition metal catalyst using the Surface Organometallic Chemistry (SOMC) approach. Chapter 1, gives an introduction to the field of MOF and their applications to catalysis through the functionalization of hydroxide containing SBUs. This chapter introduces also the SOMC strategy with an overview of its catalytic application for olefin metathesis and CO2 conversion. Chapter 2 and 3 give a detailed application of SOMC to MOFs with the selective grafting of the W(≡CtBu)(CH2tBu)3 complex on the highly crystalline and mesoporous Zr-NU-1000 MOF. The obtained single site material, Zr-Nu-1000-W, is fully characterized using state of the art experimental methods and all the steps leading to the final grafted moieties were identified by DFT. Zr-NU-1000-W is active for olefin metathesis and is further fine-tuned by activation with EtAlCl2 giving a more selective and stable catalyst. Moreover, the nature of the grafted species could be modulated by pre-activation of the initial W(≡CtBu)(CH2tBu)3 complex with dmpe giving W(≡CtBu)(=CHtBu)(CH2tBu)(dmpe) also grafted on Zr-NU-1000. Chapter 4 and 5, describe the deliberate design and bulk synthesis of a new zirconium MOF, Zr-she-MOF-2, and highlight the discovery of a new highly connected MOF, RE-urx-MOF-1, based on a careful combination of rare earth (RE) metals with heterobifunctional triangular tetrazolate-based ligand. Additionally, the replacement of the tetrazolate functionality by carboxylate, leads to the formation of a different MOF structure RE-gea-MOF-4 having the gea topology with the presence of 18-connected nonanuclear RE cluster. Both Zr-she-MOF-2 and RE-gea-MOF-4 are active for the coupling of epoxides with CO2 to form cyclic carbonate in the presence of Bu4NBr. Finally, Chapter 6 will discuss the conclusions and perspectives of this dissertation.

Metal Organic Frameworks

Catalysis

Reticular Chemistry

Carbon Conversion

Functional Materials

Olefin Metathesis

Exploring the Reactivity of Well-defined Oxide-supported Metal­Alkyl and Alkylidyne Complexes via Surface Organometallic Chemistry

Saidi, Aya

02 1900

Surface Organometallic Chemistry (SOMC) is an excellent approach to erase the gap between homogeneous and heterogeneous catalysis by grafting the molecular organometallic complex on various oxide surfaces, forming well-defined and single-site catalysts. This strategy allows for better characterization as well as the improvement and development of existing and new catalysts. These surface species could promote a wide range of catalytic applications (i.e., metathesis of hydrocarbons, hydrogenolysis of alkanes, and olefin polymerization reactions) depending on the metal center and its coordination sphere. In particular, the grafting of alkylated organometallic complexes of groups 4, 5, and 6 metals on the surface oxide is a thermodynamically favored reaction generally leading to strongly bonded well-defined surface species, which are highly reactive catalysts. This thesis has focused on the preparation, characterization, and catalytic investigation of different supported complexes that contain methyl, alkyl, and alkylidyne ligands. The first part compares the catalytic activity of [(≡Si−O−)W(-CH3)5] and [(≡Si-O-)Mo(≡CtBu)(-CH2tBu)2] surface species experimentally and by DFT calculations in the metathesis reactions of linear classical and functionalized olefins. Both pre-catalysts perform almost equally in the α-olefin metathesis reaction. However, in the functionalized olefin metathesis reaction, W pre-catalyst provides selective metathesis products and performs much better than Mo that gives a range of isomerization products. The second part deals with the synthesis and characterization of [(THF)2Zr(-CH3)4] and its grafting on silica support for the first time. The generated surface species [(≡Si−O−)Zr(CH3)3(THF)2] and [(≡Si−O−)2Zr(CH3)2(THF)2] are used for the conversion of CO2 and propylene oxide to cyclic propylene carbonates achieving a TON of 4227. The third part describes the first synthesis and characterization of the highly unstable homoleptic [Ti(-CH3)4] without any coordinating solvent. This complex was stabilized by grafting on SiO2-700, yielding two fully characterized surface species [(≡Si-O-)TiMe3] and [(≡Si-O-Si≡)(≡Si-O-)TiMe3], which were used in the hydrogenolysis reaction of propane and n-butane, with TONs of 419 and 578, respectively. Finally, the fourth part reports the immobilization and characterization of [TiMe2Cl2], an intermediate in the synthesis of [Ti(-CH3)4], on SiO2-700 resulting in [(≡Si-O-)TiMeCl2] and [(≡Si-O-)TiMe2Cl] surface species. These complexes reacted with a demethylating Lewis acid agent (BARF), forming the corresponding cationic Ti species [(≡Si-O-)TiMeCl]+ and [(≡Si-O-)TiCl2]+. Both neutral and cationic complexes were tested in the ethylene polymerization reaction affording linear HDPE with high molecular weights of 500,367 and 486,612 g/mol.

Catalysis

Methyl ligand

Surface organometallic chemistry

Olefin metathesis

CO2 conversion

Hydrogenolysis of alkanes