Chemistry of meso-Free Subporphyrins / メゾフリーサブポルフィリンの化学

Kitano, Masaaki

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第19516号 / 理博第4176号 / 新制||理||1600(附属図書館) / 32552 / 京都大学大学院理学研究科化学専攻 / (主査)教授 大須賀 篤弘, 教授 丸岡 啓二, 教授 依光 英樹 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

porphyrinoids

subporphyrins

cross-coupling reactions

substitution

borylation

400

Studies on Palladium-Catalyzed Reactions of Aryl Chlorides with Lewis Acidic Boron or Organosilicon Reagents / ルイス酸性を有するホウ素反応剤や有機ケイ素反応剤を用いたパラジウム触媒による塩化アリールの変換反応に関する研究

Yamamoto, Yutaro

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20205号 / 理博第4290号 / 新制||理||1616(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 依光 英樹, 教授 大須賀 篤弘, 教授 丸岡 啓二 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

palladium

aryl chloride

borylation

hydrodechlorination

cross-coupling reactions

400

Engaging Esters as Cross-Coupling Electrophiles

Ben Halima, Taoufik

09 August 2019

Cross-coupling reactions, where a transition metal catalyst facilitates the formation of a new carbon-carbon or carbon-heteroatom bond between two coupling partners, has become one of the most widely used, reliable, and robust family of transformations for the construction of molecules. The Nobel Prize was awarded to pioneers in this field who primarily used aryl iodides, bromides, and triflates as electrophilic coupling partners. The expansion of the reaction scope to non-traditional electrophiles is an ongoing challenge to enable an even greater number of useful products to be made from simple starting materials. The major goal of this thesis research is to improve and expand upon this field by using esters as electrophiles via the activation of the strong C(acyl)−O bond. Esters are particularly robust in comparison to other carboxylic acid derivatives used in cross-coupling reactions. Success on the activation of such inert functional group using catalysis has both fundamental and practical value. By discovering new reaction modes of this abundant functional group, synthetic routes to access novel or industrially important molecules can be improved. Chapter 1 of this thesis describes a literature overview of what has been accomplished in the field of cross coupling reactions using carboxylic acid derivatives as electrophilic coupling partners. Chapter 2 discloses the first palladium Suzuki-Miyaura couplings of phenyl esters to produce ketones. The method is efficient and robust, giving good yields of useful products. The reaction is proposed to proceed via an oxidative addition to the strong C(acyl)−O bond of the ester. In contrast to previous efforts in this field that use traditional catalysts such as Pd(PPh3)4, the developed reaction requires use of an electron-rich, bulky N-heterocyclic carbene ligand, which facilitates the strong bond activation. Furthermore, a palladium-catalyzed cross-coupling between aryl esters and anilines is reported, enabling access to diverse amides. The reaction takes place via a similar activation of the C−O bond by oxidative addition with a Pd−NHC complex, which enables the use of relatively non-nucleophilic anilines that otherwise require stoichiometric activation with strong bases to react. Chapter 3 discloses a nickel-catalyzed amide bond formation using unactivated and abundant esters. In this transformation, an accessible nickel catalyst can facilitate the activation of diverse aliphatic and aromatic esters to enable direct amide bond formation with amines as nucleophiles. No stoichiometric base, acid, or other activating agent is needed, providing exceptional functional group tolerance and producing only methanol as a by-product. This reaction is of both fundamental and practical importance because it is the first to demonstrate that simple conditions can enable Ni to cleave the C–O bond of an ester to make an oxidative addition product, which can be subsequently coupled with amines. This discovery contrasts industrially-common and wasteful methods that still require stoichiometric activating agents or multistep synthesis. Chapter 4 describes the evaluation of different types of cross-coupling reactions using methyl esters as electrophilic coupling partner. A high-throughput screening technique has been applied to this project. A combination between specific ligands, known by their efficiency to activate strong C−O bonds, and literature-based conditions has been designed for the chosen transformations. Using this strategy, two promising hits have been obtained using the same NHC ligand: a decarbonylative Suzuki-Miyaura and a decarbonylative borylation reaction.

Esters

Electrophiles

cross-coupling reactions

Suzuki-Miyaura coupling

Amide bond formation

High-throughput screening

Cross-Coupling Reactions in Flow Microreactor Systems / フローマイクロリアクターを用いたクロスカップリング反応

Moriwaki, Yuya

25 May 2015

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19183号 / 工博第4060号 / 新制||工||1626(附属図書館) / 32175 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 吉田 潤一, 教授 杉野目 道紀, 教授 松原 誠二郎 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

flow microreactor

cross-coupling reactions

organolithium compounds

organoboronic esters

flash chemistry

500

silver-iron oxide particles as heterogeneous catalysts for the cross coupling of arenes and heterocycles

Qi Wang (14223956)

07 December 2022

<p>Advances in nanomaterials research have stoked interests in the design of dispersible catalysts for specific organic transformations, with higher reaction efficiency or lower burden in post-reaction waste processing. Multicomponent heterogeneous catalysts generally offer higher catalytic performance than single-component catalysts, with metal–substrate interactions (MSI) playing a key role in their performance. This thesis focuses on silver–iron-oxide particles as heterogeneous catalysts, starting with a literature survey (Chapter 1) followed by the synthesis and catalytic properties of two novel types of Ag–Fe₃O₄ particles that show strong potential for mediating C(sp²)–H arylation reactions (Chapters 2 and 3). Silver and especially iron oxide are much less expensive than other types of metals, and the magnetic properties of the Fe₃O₄ support transferability and reuse of the active catalytic species which enables us to reduce the ratio of catalyst to reactant. These features address multiple goals outlined by the principles of green chemistry. The arylation of heterocyclic compounds is frequently used in the preparation of organic dyes, polymers, and pharmaceutical intermediates, and is a useful benchmark reaction for comparing our cross-coupling catalyst with those from prior reports. </p> <p>In Chapter 2, we describe the synthesis of colloidal silver–iron-oxide (SIO) and investigate its conversion into an efficient catalyst for C(sp²)–H arylation using novel modes of activation. This includes electrochemical activation using mild cathodic potentials, and photoactivation using a white light source. Both methods dramatically improve the efficacy of colloidal SIO as a catalyst for the cross coupling of diazonium salts with heteroaromatic rings at room temperature. High-resolution transmission electron microscopy analysis reveals that the SIO particles are primarily composed of colloidal Ag that are coated with nanosized islands of Fe₃O₄. The SIO catalysts are magnetically responsive and can be collected and reused multiple times, without requiring reactivation. The SIO is susceptible to acid degradation but can be preserved with neutralization by added base during reaction cycling. </p> <p>In Chapter 3, we describe a second-generation catalyst in which Fe₃O₄ microspheres serves as the supporting substrate for Ag islands, with synthetic control over Ag size distribution. This material does not require any activation for cross-coupling catalysis, which can be attributed to better charge transfer between the Ag islands and Fe₃O₄ substrate. A comparison of Ag–Fe₃O₄ microspheres with different Ag/Fe ratios suggests that catalytic activity correlates with smaller particle sizes, where the strongest charge-transfer interactions are likely to occur. The role of MSI between Ag and Fe₃O₄ was further explored using X-ray absorption spectroscopy. The second-generation Ag–Fe₃O₄ catalysts are far more robust than the previous version and are better able to withstand acidic degradation, with less mass loss after multiple reaction cycles and no loss in catalytic function. Lastly, we have found that Ag–Fe₃O₄ microspheres can also be an efficient catalyst for the reduction of nitro groups into amines, and describe progress toward the one-pot conversion of  nitroarenes into  cross-coupling products.  </p>

cross coupling reactions

Nanoparticles

interface charge mobility

Fonctionnalisation directe de liaisons C-H et couplages croisés pour la formation de liaisons C-C et C-N : synthèse de purines 6,8,9-trisubstituées / C-H bond direct functionalization and cross-coupling reactions for C-C and C-N bonds formation : synthesis of 6,8,9-trisubstituted purines

Vabre, Roxane

15 October 2013

La grande variété de propriétés biologiques associées au noyau purine en fait une structure privilégiée pour la conception et la synthèse de nouvelles molécules à visée thérapeutique. Cette spécificité est étroitement liée à la grande diversité de substituants pouvant être introduits sur les différentes positions du noyau purine et en particulier sur C2, C6, C8 et N9. Par conséquent, le développement de méthodes de fonctionnalisation rapides de cette famille de composés est d’un grand intérêt synthétique. Nous nous sommes focalisés sur la formation de liaisons C-C et C-N sur les positions 6 et 8 du noyau purine pour pouvoir présenter de nouveaux outils de synthèse permettant d’introduire une plus grande diversité fonctionnelle. D’une part, nous avons étudié la fonctionnalisation directe de liaisons C-H de purines, sujet encore peu exploré. En effet, de nos jours, le traditionnel couplage croisé (Negishi, Suzuki-Miyaura), utilisé pour la création de liaisons C-C, se voit de plus en plus concurrencé par ces réactions puisqu’elles ne nécessitent pas la préparation d’un partenaire organométallique. Ce sont des réactions dites à économie d’atomes. En nous basant sur l’expérience du laboratoire dans le domaine de la fonctionnalisation directe de liaisons C-H, nous avons envisagé l’alcénylation et l’alcynylation directes en position 8 de la purine, les motifs alcényle et alcynyle étant présents dans certaines purines d’intérêt biologique. D’autre part, nous nous sommes intéressés à deux méthodes de couplage croisé pallado-catalysé permettant la formation de liaisons C-N et C-C : le couplage de Buchwald – Hartwig entre une 8-iodopurine et des amides ou des amines aromatiques, et le couplage de Liebeskind – Srogl entre une 6-thioétherpurine et divers acides boroniques. / Purine is the most widely distributed N-heterocycle scaffold in the nature and its derivatives are well known for their biological and fluorescent properties. These characteristics are linked to the diversity of substituents that can be introduced, especially on the C-2, C-6, C-8 and N-9 positions. Therefore, the development of methods for rapid functionalization of this family of compounds represent a valuable asset. We focused on the formation of C-C and C-N bonds at positions 6 and 8 of the purine ring in order to provide new synthesis tools allowing the introduction of functional diversity. On the one hand, we studied the direct functionalization of C-H bonds of purines, subject still little explored. Indeed, nowadays, traditional cross-coupling reactions (Negishi, Suzuki-Miyaura), used for the creation of C-C bonds, are increasingly challenged by these reactions since they do not require the preparation of an organometallic partner. Their advantage lies in step and atom economy. Based on previous experience in our laboratory in the field of direct functionalization of C-H bonds, we envisioned direct alkenylation and alkynylation at position 8 of the purine, knowing that alkenyl and alkynyl patterns are found in purines of biological interest. On the other hand, we were interested in two pallado-catalyzed cross-coupling methods for the formation of C-N and C-C bonds : Buchwald – Hartwig coupling between 8-iodopurine and aromatic amines or amides, and Liebeskind – Srogl coupling between 6-thioétherpurine and a range of boronic acids.

Méthodologie

Purine

Couplages croisés

Methodology

Purine

Direct C-H bond functionalization

Cross-coupling reactions

The Investigation of Oxidative Addition Reactions of Metal Complexes in Cross-Coupling Catalytic Cycles Based on a Unique Methodology of Coupled Ion/Ion-Ion/Molecule Reactions

Parker, Mariah L.

01 January 2018

Popular catalytic cycles, such as the Heck, Suzuki, and Negishi, utilize metal centers that oscillate between two oxidation states (II/0) during the three main steps of catalysis: reductive elimination, oxidative addition, and transmetallation. There has been a push to use less toxic, cheaper metal centers in catalytic cycles, leading to interest in first-row transition metals, such as nickel and cobalt. With these metals, the cycles can potentially pass through the +1 oxidation state, which acts as reactive intermediates, undergoing oxidative additions to form products, potentially with radical characteristics. The oxidative addition steps of catalytic cycles are critical to determining overall rates and products, however in many cases, these steps have not been amenable to study, in either condensed phase or gas phase, in the past. Through the use of electron transfer dissociation (ETD) technology on a modified Thermo Electron LTQ XLTM mass spectrometer, it is possible to generate intermediates in these catalytic cycles, including those in unusual oxidation states. Using sequentially coupled ion/ion-ion/molecule reactions, the reduced, reactive intermediate can be readily generated, isolated, and studied.As a model set of reactions, the mono- and bis-phenanthroline complexes of Fe(I), Co(I), Ni(I), Cu(I), and Zn(I) were formed by reduction of the corresponding M(II) species in an ion/ion reaction with the fluoranthenyl radical anion. The chemistry of the M(I) species was probed in ion/molecule reactions with allyl iodide. In order to explore ligand effects and the scope of oxidative addition reagents further, bipyridine and terpyridine were studied with these five first-row transition metal complexes while using an acetate series and other substrates for oxidative additions. Through these studies, the roles of the metal and ligand in dictating the product distributions and reaction rates were assessed. Metal electron count, ligand flexibility, and coordination number are critical factors. The overall reactivity is in accord with density functional theory calculations and mirrors that of proposed intermediates in condensed-phase catalytic cycles. In addition, second- and third-row transition metals (Ru(I), Pd(I), and Pt(I)) were explored with bipyridine, mono- and bis-triphenylphosphine, and 1,2-bis(diphenylphosphino)benzene ligation schemes. A variety of oxidative addition reagents were surveyed to determine the scope of reactivity and preference toward metal-carbon bond formation or carbon radical formation.

gas-phase reactions

ion/ion reactions

ion/molecule reactions

catalysis

cross-coupling reactions

Inorganic Chemistry

Organic Chemistry

Physical Chemistry

Distorted arenes by Scholl cyclizations, towards twisted carbon nanoribbons

Pradhan, Anirban

23 September 2013

Carbon nanoribbons are today of great interest as graphene segments with modulable electronic properties. Whilst top down techniques give giant ribbons, bottom-up organic synthesis may lead to exactly designed nanoribbons of controlled geometries. The Scholl reaction is a precious chemical tool for that purpose since it yields efficiently to the graphitization of long and flexible polyphenylene precursors.Surprisingly, twisted structures may be obtained preferentially even if less crowded isomers are also feasible. It has been shown that, against all expectation, even a strong steric hindrance has no marked effect on regioselectivity and highly twisted polycyclic aromatic hydrocarbons are sometimes preferentially formed, whereas their flat and more symmetrical isomers are only obtained in minority. Highly twisted structures such as hexabenzotriphenylene (HBTP) may then be obtained very easily from flexible polyphenylene precursors.After discovering this unexpected regioselectivity, we used it on purpose to form polyhelicenic species. Attempts to prepared hexaphenanthrotriphenylene (HPTP) were unsuccessful due to reactivity issues when synthesizing the corresponding flexible precursors. By using a new versatile strategy leading to an advanced common precursor, several C3-symmetrical flexible substrates have been synthesized and submitted to Scholl reaction. The expected [6]helicenes were not obtained and rearranged products were formed instead, but TMS-bearing HBTP could be prepared, as well as a hexabenzocoronene (HBC) which exceptionnal solubility is due to the distortion of the aromatic core under the effect of bulky tert-butyl substituents in bay regions.The easily formed [5]helicene fragment has been incorporated in the design of twisted carbon nanoribbons that would be composed of a succession of such motifs. As a test reaction, the corresponding monomer and dimer have been synthesized with an excellent yield and fully characterized. Their X-ray structures have even been determined, giving interesting information about their configuration. A more general strategy has then been developed and optimized for the systematic synthesis of longer oligomers of twisted nanoribbons. Using this technique, the trimer and tetramer have been synthesized and characterized by mass spectrometry.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Polycyclic aromatic compounds (PAC)

Carbon nanoribbons

Helicenes

Scholl reaction

Catalyzed cross-coupling reactions

Sintese e heterogeneização de complexos de paladio : aplicação em reações de acoplamento C-C / Synthesis and heterogeneization of palladium complexes : application in C-C cross-coupling reactions

Sato, Cintia Akemi

13 December 2007

Orientador: Regina Buffon / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-11T02:19:50Z (GMT). No. of bitstreams: 1 Sato_CintiaAkemi_M.pdf: 2497710 bytes, checksum: ed234ce28b62278b8777a943791d0170 (MD5) Previous issue date: 2007 / Resumo: Neste trabalho, foram sintetizados complexos de paládio em que os ligantes fosforados estão ¿ancorados¿ em ciclofosfazenos. Estes complexos, em solução ou imobilizados em matrizes inorgânicas, foram testados nas reações de acoplamento de Suzuki (entre o ácido fenilborônico e o bromobenzeno, por exemplo), de Stille (entre o tributilvinilestanho e o bromotolueno) e de Heck (entre o estireno e o bromobenzeno). O resultado catalítico obtido com o catalisador sintetizado, em fase homogênea, na reação de Heck (TON = 3900, em 6 horas), foi muito bom, sendo superior a um catalisador análogo descrito na literatura. Na reação de Stille, o complexo, em fase homogênea, apresentou um ótimo resultado (TON = 4340, em 4 horas). Na reação de Suzuki, em fase homogênea, o TON obtido (123, em 24 horas) foi bom e comparável à literatura. Já em fase heterogênea, com o complexo encapsulado em matriz de sílica via processo solgel, os resultados obtidos, tanto na primeira reação quanto na primeira e segunda reciclagens, são superiores aos apresentados na literatura e apresentam o TON próximo ao obtido em fase homogênea, no mesmo tempo (92, 94 e 92 respectivamente), sem perda de desempenho. Estudos prospectivos para a imobilização do complexo em sílica foram realizados. O catalisador foi sintetizado com ligantes contendo grupos hidrolisáveis e ancorado em sílica. Este sistema foi testado nas reações de acoplamento de Stille e Suzuki, apresentando um bom desempenho nas duas reações (TON = 1400, em 4 horas, e 49, em 24 horas, respectivamente) sem constatação visual de lixiviação de paládio / Abstract: In this work, palladium complexes, in which phosphored ligands are ¿anchored¿ to cyclophosphazenes were synthesized. These complexes, in solution or immobilized in inorganic matrices, were tested in the Suzuki cross-coupling reaction (between phenylboronic acid and bromobenzene, for example), the Stille cross-coupling reaction (between tributylvinyltin and 3-bromotoluene) and the Heck reaction (between styrene and bromobenzene). The catalytic results obtained with the synthesized catalyst, in homogeneous phase, in the Heck reaction (TON = 3900, in 6 hours), was very good, better than those reported for a similar catalyst described in literature. In the Stille reaction, the complex, in homogeneous phase, presented an excellent result (TON = 4340, in 4 hours). In the Suzuki reaction, in homogeneous phase, the obtained TON (123, in 24 hours) was good and comparable to literature. In heterogeneous phase, with the complex encapsulated in silica matrix via the sol-gel process, the obtained results, in the first reaction as well as in the first and second recycling, are higher than those presented in literature and presented the TON close to that obtained in homogeneous phase, in the same reaction time (92, 94 and 92 respectively), without loss of performance. Prospective studies for the immobilization of the complex in silica were done. The catalyst was synthesized with ligands containing hydrolysable groups and anchored in silica. This system was tested in Stille and Suzuki cross-coupling reactions, showing a good performance in both reactions (TON = 1400, in 4 hours, and 49, in 24 hours, respectively) without visual evidence of palladium leaching / Mestrado / Quimica Inorganica / Mestre em Química

Complexos de paládio

Acoplamento C-C

Catálise

Imobilização de complexos de paládio

Catalysis

Palladium complexes

Cross-coupling reactions

Immobilization of palladium complexes

Synthesis and Catalytic Activities of Nickel Complexes Bearing Flexible Tridentate Ligands

Nambukara Wellala, Nadeesha P.

30 October 2017

No description available.

Chemistry

Organic Chemistry

Inorganic Chemistry

Nickel Complexes

Pincer Complexes

CO2 Reduction

C S Cross Coupling Reactions

Hydride Complexes

Protonation