Transfert ultrarapide d’électron et transfert modéré d’énergie au sein d’assemblages supramoléculaires de colorants et d’un cluster de palladium / Ultrafast electron and moderate energy transfers within supramolecular assemblies of dyes and a palladium cluster

Luo, Peng

January 2016

Résumé : Les transferts d’électrons photo-induits et d’énergie jouent un rôle primordial dans un grand nombre de processus photochimiques et photobiologiques, comme la respiration ou la photosynthèse. Une très grande quantité de systèmes à liaisons covalentes ont été conçus pour copier ces processus de transferts. Cependant, les progrès sont, en grande partie, limités par les difficultés rencontrées dans la synthèse de nouveaux couples de types donneurs-accepteurs. Récemment, des espèces utilisant des liaisons non-covalentes, comme les liaisons hydrogènes, les interactions [pi]-[pi], les liaisons de coordination métal-ligands ou encore les interactions électrostatiques sont le centre d’un nouvel intérêt du fait qu’ils soient plus faciles à synthétiser et à gérer pour obtenir des comportements de transferts d’électrons ou d’énergie plus flexibles et sélectifs. C’est dans cette optique que le travail de cette thèse a été mené, i.e. de concevoir des composés auto-assemblés avec des porphyrines et un cluster de palladium pour l’étude des transferts d’électrons photo-induits et d’énergie. Cette thèse se divise en quatre parties principales. Dans la première section, le chapitre 3, deux colorants porphyriniques, soit le 5-(4-carboxylphényl)-10, 15, 20-tristolyl(porphyrinato)zinc(II) (MCP, avec Na+ comme contre-ion) et 5, 15-bis(4-carboxylphényl)-15, 20-bistolyl(porphyrinato)zinc(II) (DCP, avec Na+ comme contre-ion) ont été utilisés comme donneurs d’électrons, et le [Pd3(dppm)3(CO)]2+ ([Pd32+], dppm = (Ph2P)2CH2, PF6‾ est le contre-ion) a été choisi comme accepteur d’électrons. La structure de l’assemblage [Pd32+]•••porphyrine a été élucidée par l’optimisation des géométries à l’aide de calculs DFT. La spectroscopie d’absorption transitoire (TAS) montre la vitesse de transferts d’électrons la plus rapide (< 85 fs, temps inférieurs à la limite de détection) jamais enregistrée pour ce type de système (porphyrine-accepteur auto-assemblés). Généralement, ces processus sont de l’ordre de l’échelle de la ps-ns. Cette vitesse est comparable aux plus rapides transferts d’électrons rapportés dans le cas de systèmes covalents de type porphyrine-accepteur rapide (< 85 fs, temps inférieurs à la limite de détection). Ce transfert d’électrons ultra-rapide (ket > 1.2 × 1013 s-1) se produit à l’état énergétique S1 des colorants dans une structure liée directement par des interactions ioniques, ce qui indique qu’il n’est pas nécessaire d’avoir de forts liens ou une géométrie courbée entre le donneur et l’accepteur. Dans une deuxième section, au chapitre 4, nous avons étudié en profondeur l’effet de l’utilisation de porphyrines à systèmes π-étendus sur le comportement des transferts d’électrons. Le colorant 9, 18, 27, 36-tétrakis-meso-(4-carboxyphényl)tétrabenzoporphyrinatozinc(II) (TCPBP, avec Na+ comme contre-ion) a été sélectionné comme candidat, et le 5, 10, 15, 20-tétrakis-meso-(4-carboxyphényl)porphyrineatozinc(II) (TCPP, avec Na+ comme contre-ion) a aussi été utilisé à des fins de comparaisons. TCPBP et TCPP ont, tous deux, été utilisés comme donneurs d’électrons pour fabriquer des assemblages supramoléculaires avec le cluster [Pd32+] comme accepteur d’électrons. Les calculs DFT ont été réalisés pour expliquer les structures de ces assemblages. Dans les conditions expérimentales, ces assemblages sont composés principalement d’une porphyrine avec 4 équivalents de clusters. Ces systèmes ont aussi été investigués par des mesures de quenching (perte de luminescence), par électrochimie et par d’autres techniques. Les transferts d’électrons (< 85 fs; temps inférieurs à la limite de détection) étaient aussi observés, de façon similaire aux assemblages MCP•••[Pd32+] et [Pd32+]•••DCP•••[Pd32+]. Les résultats nous indiquent que la modification de la structure de la porphyrine vers la tétrabenzoporphyrine ne semble pas influencer le comportement des cinétiques de transferts d’électrons (aller ou retour). Dans la troisième section, le chapitre 5, nous avons synthétisé la porphyrine hautement [pi]-conjuguée: 9, 18, 27, 36-tétra-(4-carboxyphényléthynyl)tétrabenzoporphyrinatozinc(II) (TCPEBP, avec Na+ comme contre-ion) par des fonctionnalisations en positions meso- et β, β-, qui présente un déplacement vers le rouge de la bande de Soret et des bandes Q. TCPEBP était utilisé comme donneur d’électrons pour fabriquer des motifs supramoléculaires avec le [Pd32+] comme accepteur d’électrons. Des expériences en parallèle ont été menées en utilisant la 5, 10, 15, 20-tétra-(4-carboxyphényl)éthynylporphyrinatozinc(II) (TCPEP, avec Na+ comme contre-ion). Des calculs DFT et TDDFT ont été réalisés pour de nouveau déterminer de façon théorique les structures de ces systèmes. Les constantes d’association pour les assemblages TCPEBP•••[Pd32+]x sont les plus élevées parmi tous les assemblages entre des porphyrines et le cluster de palladium rencontrés dans la littérature. La TAS a montré, encore une fois, des processus de transferts d’électrons dans des échelles de l’ordre de 75-110 fs. Cependant, les transferts de retour d’électrons sont aussi très rapides (< 1 ps), ce qui est un obstacle potentiel pour des applications en cellules solaires à pigment photosensible (DSSCs). Dans la quatrième section, le chapitre 6, les transferts d’énergie triplets (TET) ont été étudiés pour les assemblages MCP•••[Pd32+] et [Pd32+]•••DCP•••[Pd32+]. Les analyses spectrales des états transitoires dans l’échelle de temps de la ns-[mu]s démontrent de façon évidente les TETs; ceux-ci présentent des transferts d’énergie lents et/ou des vitesses moyennes pour des transferts d’énergie T1-T1 (3dye*•••[Pd32+] → dye•••3[Pd32+]*) opérant à travers exclusivement le mécanisme de Förster avec des valeurs de kET autour de ~ 1 × 105 s-1 selon les mesures d’absorption transitoires à 298 K. Des forces motrices non-favorables rendent ces types de processus non-opérants ou très lents dans les états T1. L’état T1 de [Pd32+] (~8190 cm-1) a été qualitativement déterminé par DFT et par la mise en évidence de l’émission S0 ← Tn retardée à 680-700 nm provenant de l’annihilation T1-T1, ce qui fait que ce cluster peut potentiellement agir comme un donneur à partir de ses états Tn, et accepteur à partir de T1 à l’intérieur de ces assemblages. Des pertes d’intensités de types statiques pour la phosphorescence dans le proche-IR sont observées à 785 nm. Ce travail démontre une efficacité modérée des colorants à base de porphyrines pour être impliquée dans des TETs avec des fragments organométalliques, et ce, même attachées grâce à des interactions ioniques. En conclusion, les assemblages ioniques à base de porphyrines et de clusters de palladium présentent des propriétés de transferts d’électrons S1 ultra-rapides, et des transferts d’énergie T1 de vitesses modérées, ce qui est utile pour de possibles applications comme outils optoélectroniques. D’autres études, plus en profondeur, sont présentement en progrès. / Abstract : Photoinduced electron and energy transfers play the pivotal role in various photochemical and photobiological redox processes including photosynthesis and respiration. Abundant covalently bonded systems have been designed to mimic the natural electron and energy transfer processes. However, the progress is often interfered by the difficulties to synthesize novel and versatile covalent donor-acceptor pairs. Recently, entities utilizing non-covalent interactions including hydrogen-bonding, [pi]-[pi] stacking, metal-ligand coordination and electrostatic interactions are becoming a hot topic since they are easy to be fabricated and tuned for selective and flexible electron and energy transfer behaviors. In this respect, the work presented in this thesis designed self-assemblies with porphyrins and a palladium cluster for photoinduced electron and energy transfers. It includes four main sections. In the first section, Chapter 3, two porphyrinic dyes, 5-(4-carboxylphenyl)-10, 15, 20-tristolyl(porphyrinato)zinc(II) (MCP, as sodium salt) and 5, 15-bis(4-carboxylphenyl)-15, 20-bistolyl(porphyrinato)zinc(II) (DCP, as sodium salt), were used as electron donors, and [Pd3(dppm)3(CO)]2+ ([Pd32+], dppm = (Ph2P)2CH2, as PF6‾ salt) cluster was adopted as the electron acceptor. The structure of [Pd32+]•••porphyrin assemblies was elucidated by geometry optimization using Density Functional Theory (DFT) calculations. Transient absorption spectroscopy (TAS) indicated a record fast electron transfer rate (< 85 fs, the time resolution limit) among the porphyrin-acceptor self-assemblies. Typically, these occur in ps-ns time scale. This rate is also comparable to the fastest electron transfer rate reported for the covalently linked porphyrin-acceptor systems (~ 50 fs, the time resolution limit). The ultrafast photo-induced electron transfers (ket > 1.2 × 1013 s-1) occurring at the S1 levels of the dyes in the structurally well-defined “straight up” ionic assemblies indicate that it is not necessary to have a strong bond and bent geometry between the donor and acceptor. In the second section, Chapter 4, we further studied the effect of using π-extended porphyrins on the electron transfer behavior of these assemblies. 9, 18, 27, 36-Tetrakis-meso-(4-carboxyphenyl)tetrabenzoporphyrinatozinc(II) (TCPBP, as a sodium salt) was selected as the candidate, and the 5, 10, 15, 20-tetrakis-meso-(4-carboxyphenyl)porphyrinatozinc(II) (TCPP, as a sodium salt) dye was also studied for comparison purposes. TCPBP and TCPP were both utilized as electron donors to fabricate supramolecular assemblies with the [Pd32+] cluster as the electron acceptor. DFT calculations were used to explain the structure of these assemblies. Under the experimental conditions used, these assemblies mainly exist in the form of one porphyrin with four equivalent clusters. These systems were also investigated by quenching measurements, electrochemistry, and other techniques. Ultrafast electron transfers (< 85 fs; time resolution limit) were also observed, which is similar as those for MCP•••[Pd32+] and [Pd32+]•••DCP•••[Pd32+] assemblies. The results indicate the structural modification from porphyrin to tetrabenzoporphyrin does not seemingly influence the kinetic behavior of the forward and back electron transfers. In the third section, Chapter 5, we synthesized a highly [pi]-conjugated porphyrin, 9, 18, 27, 36-tetra-(4-carboxyphenylethynyl)tetrabenzoporphyrinatozinc(II) (TCPEBP, as a sodium salt) by meso- and β, β-bifunctionalization, which exhibits large red shift of the Soret and Q-bands. TCPEBP was utilized as electron donors to fabricate supramolecular motifs with [Pd32+] cluster as the electron acceptor. Parallel experiments were conducted using 5, 10, 15, 20-tetra-(4-carboxyphenyl)ethynylporphyrinatozinc(II) (TCPEP, as a sodium salt). DFT and TDDFT calculations were applied to elucidate the structure of these assemblies. Binding constants for TCPEBP•••[Pd32+]x is the largest one among all the assemblies with porphyrin and palladium cluster. TAS showed again the ultrafast electron transfer process within the 75-110 fs time frame. However, the back electron transfers are also very fast (< 1 ps), which may be a potential obstacle for future applications in dye-sensitized solar cells (DSSCs). In the fourth section, Chapter 6, triplet energy transfers (TET) of the assemblies MCP•••[Pd32+] and [Pd32+]•••DCP•••[Pd32+] were studied. The transient spectral analysis in the ns-[mu]s time scale clearly demonstrates evidence for TET, which shows a slow to medium T1-T1 energy transfer (3dye*•••[Pd32+] → dye•••3[Pd32+]*) operating through a Förster mechanism exclusively with kET values of ~ 1 × 105 s-1 based on transient absorption measurements at 298 K. Unfavourable reductive and oxidative driving forces make this type of process inoperative or very slow in the T1 states. The T1 state of [Pd32+] (~8190 cm-1) has been quantitatively determined by DFT computations and by evidence for a delayed S0 ← Tn emission at 680-700 nm arising from T1-T1 annihilation, which makes this cluster potentially acting as the energy donor from its Tn state, and T1 acceptor within the assemblies. The static quenching of their near-IR phosphorescence at 785 nm was observed. This work demonstrated a moderate efficiency of the porphyrin dye to be involved in TET with an organometallic fragment, even when attached through ionic interactions. Conclusively, ionic assemblies with porphyrins and palladium clusters exhibit ultrafast S1 electron transfer and moderate T1 energy transfer properties, which is useful for possible application as optoelectronic devices. Further research in more depth is in progress.

Electron Transfer

Energy Transfer

Supramolecular Assembly

Porphyrin

Palladium Cluster

Palladium catalysed allene carbocyclisation

Li, Meiling

January 2010

In this thesis, firstly, a Pd-catalysed diastereoselective carbocyclisation of allenes with aryl halides or vinyl iodides was designed and developed to form arylative or vinylative spirolactam compounds. High yields and diastereoselectivities were obtained in the presence of Pd₂(dba)₃/dppe and K₂CO₃ in DMSO at 70 &deg;C, particularly when spiropiperidin-2-ones were formed. The method is simple to perform and broad in scope. Having established the diastereoselective methodology for the arylative or vinylative allene carbocyclisation, a Pd-catalysed enantioselective version was developed by using bisoxazolines as chiral ligands. Aryl halides and vinyl iodides were investigated in this carbocyclisation. High yields and enantioselectivities were obtained in the presence of Pd(OAc)₂, a bisoxazoline ligand <strong>L7d</strong> derived from L-isoleucine and Ag₃PO₄ in 1,2-dichloroethane at 70 &deg;C. No olefin isomerisation was observed when cis-vinyl iodides were used. The method is mild, efficient and broad in scope. A palladium catalysed diastereoselective allene carbocyclisation reaction was developed via enamine catalysis and palladium catalysis, which allows for the efficient carbocyclisation of formyl or ketone allenes. Good yields and high diastereoselectivities were obtained in the presence of Pd(OAc)₂ and pyrrolidine in toluene at 60 °C when formyl allenes were investigated. The cyclisation is diastereoselective and can also performed as a catalytic asymmetric reaction by using prolinol derivatives as chiral catalysts. Good yields and high diastereo- and enantioselectivities were obtained in the presence of catalyst <strong>(S)-L19</strong>. Additionally, a boronic acid catalysed ene carbocyclisation of acetylenic dicarbonyl compounds was developed. An attempted transesterification of a &beta;-ketoester substrate bearing a pendent terminal alkyne substituent at the &beta;-position led to the discovery of an efficient 3-nitrobenzeneboronic acid catalysed ene carbocyclisation of acetylenic dicarbonyl compounds. The reaction is easy to perform, efficient, broad in scope and provides a convenient transition metal-free alternative to existing catalytic protocols.

547.6

Palladium-catalysed heterocycle synthesis

Sadig, Jessie E. R.

January 2012

Chapter 1 is a literature review of selected palladium-catalysed aryl C-N and C-S bond forming reactions. The application of these reactions to the synthesis of heterocycles is also discussed. Chapter 2 highlights the importance of the benzimidazole motif and gives a brief discussion of the existing routes to this scaffold. The utility of N-(o-halophenyl)imidoyl chlorides and imidates as precursors to heterocycles is demonstrated in a palladium-catalysed reaction with N-nucleophiles to afford benzimidazole products. Chapter 3 provides a brief introduction to the synthesis of benzothiazoles and describes efforts towards the use of our established substrates for the preparation of these heterocycles. This is achieved via reaction of N-(o-chlorophenyl)imidoyl chlorides with a sulfur nucleophile in a metal-free process. Chapter 4 is a literature review of palladium-catalysed carbonylation chemistry with specific focus on aminocarbonylation and thiocarbonylation reactions of aryl halides. Heterocycle syntheses which employ such carbonylative methods are also discussed. Chapter 5 describes existing protocols for the synthesis of quinazolinones. A novel palladium-catalysed synthesis of these heterocycles from the reaction of our imidate substrates with an amine and carbon monoxide is described. This further demonstrates their utility as general heterocycle precursors

547

Pd catalysed synthesis of phosphines for homogeneous catalysis

Damian, Karen Serena

January 2009

The synthesis of ligands has been identified as the limitation for wider application of catalytic asymmetric synthesis. Indeed, synthesis of phosphorus-based ligands, has been often shown to be challenging and not always efficient. It has also been observed that subtle changes in the ligand structure can lead to big differences in the catalytic activity of the ligand when coordinated to a metal. Therefore, it was considered useful to develop a methodology in order to obtain a library of phosphines. The first chapter of the thesis is a review of recent development in catalytic phosphine synthesis. In the second chapter of this thesis, the microwave mediated Suzuki cross coupling reaction has been investigated. In particular, attention has been focussed on the coupling of different arylboronic acids to chloroarylphosphine oxides, which are, in general, considered challenging coupling partners for this type of reaction. The reaction conditions have been optimised starting from the coupling of phenylboronic acid to tris(4-chlorophenyl)phosphine oxide. Different solvents, bases, and catalysts have been then tested and the better conditions have been developed for this substrate. Indeed, it was shown that the coupling occurs in only 30 minutes at 140°C, leading to reasonably high yields. These conditions were then applied to two other different chloroarylphosphine oxides with a range of boronic acids, with the aim to verify if the optimised reaction conditions could be applied to other substrates and it was noticed that good yields could be attained. This methodology led us to obtain a library of phosphine oxides. It was then decided to investigate the reduction of phosphine oxides under microwave irradiation. This reaction occurs under conventional heating but it can take several hours. It was observed that reaction times could be importantly reduced when reducing some phosphine oxides under microwave heating. It was found that some phosphine oxides are reduced rapidly under conventional conditions but for more difficult substrates to reduce there are significant advantage to microwave method. We decided to investigate the microwave mediated P-C bond forming reaction, with the aim to rapidly synthesise a library of phosphines cleanly. The conditions were optimised at first using o- trifluoromethylbromobenzene as the substrate. Once the appropriate reaction conditions and catalyst were identified, the reaction was run on other substrates to verify that this could be a general methodology for the synthesis of phosphines. It was found that it is indeed a general method for the synthesis of monophosphines. However, the synthesis of diphosphines with the microwave assisted P-C bond forming reaction on dibromo- and diiodo- aryl compounds proved to be very challenging. The fourth chapter presents different attempts for the synthesis of the new ligand Ph-DuPHOS. The synthesis of this ligand was considered interesting because of the previous results of other phospholane-based ligands, such as Ph-BPE and Me-DuPHOS. However, the synthesis of this ligand has proven to be elusive. A monodentate P-N phospholane-based ligand was prepared and its catalytic activity was tested in the rhodium catalysed hydrogenation of alkenes. Moreover, a bidentate (1,2-bisphospholano)xylene ligand was also prepared and its catalytic activity was also tested in the rhodium catalysed hydrogenation of alkenes. This latter ligand was also used in the hydroxycarbonylation of styrene, since for this reaction bulky diphosphines are required to give branched selectivity. In hydroxycarbonylation it is very rare to give good branched selectivity and there were no examples of substantial enantioselectivity prior to this work. The high regioselectivity and moderate e.e.’s observed suggest promise for future studies. Finally, mechanistic studies on the hydroxycarbonylation of styrene have been carried out in order to investigate the intermediates involved in the reaction as well as the role of the promoters. The possibility of (1-chloroethyl)benzene was proposed as the active intermediate of the reaction. Our results have disproved this possibility, suggesting that the reaction is likely to proceed through the hydride mechanism.

541.39

Control over assembly and interpenetration of Pd-based coordination cages

Zhu, Rongmei

24 March 2017

No description available.

540

supramolecular

coordination cage

self-assembly

palladium

Chemie  (PPN62138352X)

Studies Toward The Total Synthesis Of Subincanadine E

Sadlowski, Corinne Marie

01 January 2015

Progress towards a concise total synthesis of subincanadine E is reported. This natural product was first isolated from the Picralima nitida cell suspension culture line in 1982 under the name pericine and later in 2002 from Aspidosperma subincanum as subincanadine E. It is the most potent compound of its class with in vitro cytotoxicity against both murine lymphoma L1210 and human epidermoid carcinoma KB cells (LD50, 0.3 ug/mL and 4.4 ug/mL, respectively) and was found to be six times more potent than codeine as an opiate agonist in a 3H-naloxone binding study (IC50, 0.6 umol/L). The first-generation synthesis produced an undesired internal olefin that, upon attempted isomerization, catalyzed an unusual intermolecular Diels-Alder reaction. A revised second-generation synthesis employed (±)-harmicine and showcased an intramolecular Pd-catalyzed cross-coupling reaction that furnished an unanticipated 5-membered ring instead of the predicted 6-membered ring via methylene linker activation. Further studies utilizing an amide intermediate and organocuprate chemistry produced no desired carbon-carbon bond formation. A third-generation synthesis was carried out from enantiopure (S)-carvone. This route explored regioselective oxime formation and protecting group manipulations for a subsequent Beckmann rearrangement, which provided the first access to 5-amino derivatives of carvone. An intramolecular Pd-catalyzed cross-coupling reaction was performed to construct the aza-bicycle prior to indole installation. Contingent on its success, indole introduction and a double alkylation would provide an akuammicine-like scaffold that can ring-open upon hydride exposure to afford (15S)-subincanadine E in 16 overall steps. This work accomplished 10 steps toward the first total asymmetric synthesis of (15S)-subincanadine E.

Beckmann

carvone

cross-coupling

palladium

pericine

subincanadine E

Chemistry

From palladium to iron : towards more sustainable catalysis

Jones, Alison Sarah

January 2015

The construction of bonds in a controlled and selective manner and the development of operationally simple, general and reliable methods to achieve these aims remains a key goal of chemical synthesis and the countless industries it impacts upon. With this in mind, the chemo-, regio- and stereoselective introduction of a number of functionalities into small molecules was investigated. Traditionally the majority of functionalisations have used precious metals; the scope of transformations that can be achieved using these catalysts is remarkable. Palladium in particular has found widespread application in new bond-forming processes and, in addition to cross-coupling reactions, palladium catalysis has been used to effect a wide variety of asymmetric reactions. This work describes investigations into the palladium-catalysed enantioselective electrophilic fluorination of azaarylacetates and amides A2 and the oxidative annulation of ferrocene derivatives A4 (Scheme A1). Both products have structural significance; heterocycles and stereogenic fluorinated centres, present in A3, are important motifs in the pharmaceutical industry, and ferrocenes are important rigid scaffolds in chiral ligands such as those in the Josiphos family e.g. A7. Scheme A1. Palladium catalysis for a) enantioselective fluorination and b) oxidative annulation Whilst a general catalyst remained elusive for the asymmetric fluorination of azaarylacetates and amides, benzoxazole-containing substrates were consistently fluorinated with excellent enantioselectivity (up to 96% ee) using palladium catalyst A1 (Scheme 1a). The oxidative annulation of ferrocene derivatives proved challenging and although the reaction was successful, the product could only be isolated in up to 24% yield (Scheme 1b). In order to determine the yield-limiting step of the reaction, mechanistic studies were conducted and palladacycle A6 was synthesised as a possible reaction intermediate. Recently there has been a shift towards the development of more sustainable, environmentally benign and economic catalyst systems and iron is quickly becoming recognised as a viable alternative owing to its high natural abundance and low toxicity. A general iron-catalysed hydrofunctionalisation procedure is described that was used to form a wide variety of carbon-carbon and carbon-heteroatom bonds (Scheme A2). Scheme A2. Iron catalysis for carbon-carbon and carbon-heteroatom bond formation With just 0.5 mol% iron catalyst, the broad scope formal hydrofunctionalisation of styrene derivatives was achieved using commercially available and bench-stable catalysts and reagents. An iron-catalysed highly regioselective hydromagnesiation gave a common benzylic Grignard reagent, which was reacted with an array of electrophiles in a highly chemo- and regioselective manner. Significantly, the products of formal hydroboration, hydrosilylation and cross-coupling reactions were obtained.

546

Ferrocenylpyrazolyl nickel(II) and palladium(II) complexes as pre-catalysts for ethylene and higher α-olefins reactions

02 July 2015

Ph.D. (Chemistry) / Compounds 3-ferrocenylpyrazole (L1) 3-ferrocenyl-5-methylpyrazole (L2) and 4- ferrocenyl-1-methyl diketone (L7) were synthesized according to literature procedure, while compounds 3-ferrocenylpyrazolyl-methylenepyridine (L3), 3-ferrocenyl-5- methylpyrazolyl-methylenepyridine (L4), 3-ferrocenylpyrazolyl-ethyl amine (L5) and 3- ferrocenyl-5-methylpyrazolyl-ethylamine (L6) were prepared by phase transfer alkylation of the 2,6-bis(bromomethyl)pyridine or 2-bromoethylamine with the appropriate ferrocenylpyrazole L1 or L2 in a 1:1 ratio. These compounds L3-L6 show structural isomers labelled a and b. The isomers were in a ratio of 4:1 for L3 and L4 while for L5 and L6 the isomers were 2:1 ratio...

Ethylene - Synthesis

Palladium catalysts

Nickel catalysts

Alkenes - Synthesis

Synthesis of Dibenzofurans via a Palladium Catalyzed Oxidative Ring Closure Reaction

Akram, Sadia

01 May 2013

The cannabinoid partial agonist BAY 59-3704 has been identified as an attractive target to explore structure-activity relationships at cannabinoid receptors for the development of a therapeutic agent for psychostimulant addiction. This thesis will describe the studies associated with the optimization of a palladium-catalyzed oxidative ring closure reaction for the synthesisof dibenzofuran analogues from substituted diaryl ethers. These dibenzofurans are viewed as rigid analogues of BAY 59-3704 and will provide useful information about molecular interactions at cannabinoid receptors. The scope and limitations of the palladium-catalyzed oxidative ring closure reaction as it relates to the synthesis of the target dibenzofuran analogues will be presented.

Chemistry

Synthesis of gold and palladium thiolato complexes and their applications as sulfur dioxide sensors

10 March 2010

M.Sc. / [AuCl(PPh3)] was reacted with mixed thiols in the presence of silver(I) oxide, resulting in complexes of the type [Au(SC6H4X)(PPh3)] X= Cl, NH2,CH2, forming silver chloride as a by-product. In addition to the above series [Au(SCH2(C6H4)3(2-C6H5(C6H4N)] was prepared via a different route, where [AuCl3(2-C6H5(C6H4N)] was reacted with benzyl mercaptan under reflux in the presence of silver(I) oxide for 3 h, forming silver chloride as a by-product. Palladium complex [PdCl2(2-C6H5(C6H4N)] was prepared by reacting [PdCl2(MeCN)] with 2-phenylpyridine at room temperature for 2 h. All complexes were characterized by 1H, 13C, 31P{H} NMR, IR, mass spectrometry and elemental analysis. Characterization of the starting materials [AuCl3(2-C6H5(C6H4N)] and [PdCl2(2- C6H5(6H4N)] by single crystal X-ray diffraction confirmed their chemical formula. All complexes were reacted with sulfur dioxide (SO2) and the reactions were monitored by electrochemistry and UV-vis spectroscopy. The electrochemical study of the complexes, using cyclic voltammetry (CV) and Osteryoung square wave voltammetry (OSWV), showed one anodic peak, which is due to gold(I/III) and an unresolved peak due to thiolate ligand. Upon bubbling of SO2 to the complexes, there was an immediate change of colour from clear to yellow, the CV results showing an increase in current of the gold(I/III) peak. UV-vis spectroscopy studies showed a shift of peak form 250-286 nm, upon bubbling of SO2 to complexes.

Gold compounds synthesis

Palladium compounds synthesis

Thiols

Ligands

Sulfur dioxide