Direct comparison of homogeneous and heterogeneous palladium(II) catalysts for Suzuki-Miyaura cross-coupling reactions

Crawford, Katherine Alexis

30 March 2015

The syntheses and catalytic properties of four new 1,2-acenaphthenyl N-heterocyclic carbene-supported palladium(II) catalysts are presented. The acenaphthenyl carbene can be prepared using either mesityl or 2,6-diisopropyl N-aryl substituents. In addition, two new heterogeneous analogs were synthesized with 2,6-diisopropyl N-aryl substituents that were anchored through the backbone to an insoluble silica-support. Comprehensive catalytic studies of the Suzuki coupling of aryl halides with aryl boronic acids were carried out. In general, the homogeneous diisopropyl-functionalized catalyst was found to exhibit superior selectivity and reactivity. A comparison of the performances of the aforementioned catalysts in toluene, dichloromethane and aqueous solutions are also presented. In organic solvents, the catalysts were found to be proficient for the homogeneous Suzuki coupling of aryl iodides, bromides and chlorides with boronic acids at low temperatures (35‒40 °C). Similar reactions that were carried out in aqueous media resulted in the formation of insoluble colloidal catalytic species. Nevertheless, these species still retained high activities in terms of in the Suzuki reaction with aryl chlorides. Moreover, the heterogeneous Pd precipitates can be easily recovered for subsequent use by means of filtration. The activation energies that were determined for the aryl bromide-based Suzuki reactions were found to fall in the range, 159.2‒171.2 kJ mol⁻¹ in organic solvents and 111.3‒115.9 kJ mol⁻¹ in water. The corresponding activation energy for the aryl chloride was found to be 321.8 kJ mol⁻¹ in aqueous media using the homogeneous diisopropyl-functionalized carbene catalyst. Conversely, the heterogeneous catalyst exhibited reactivity toward aryl iodides and bromides exclusively, and required significantly higher temperatures and catalyst loadings in both toluene and water. Additional experimental trials that were performed in tetrahydrofuran solution at lower temperatures resulted in substantially larger catalytic conversions. The heterogeneous catalyst allowed for easy separation and recovery. However, the catalyst exhibited a significant decrease in reactivity toward the aryl halides after two consecutive trials. / text

Suzuki-Miyaura coupling

Palladium catalysts

Homogeneous and heterogeneous catalysis

Organometallic reagents for catalytic cross-coupling

Pearson, Mark

January 1992

Phosphine complexes of nickel and palladium provide the best catalysts for the homogeneous catalysed carbon-carbon bond forming reaction between an organometallic nucleophile and an organic electrophile. Use of a homochiral ligand on the catalyst can lead to stereoselectivity in the cross-coupling reaction, with high ee's of coupled product being obtained. The processes of selectivity in the transmetalation step of the catalytic cycle have not been elucidated and the initial aim of the project was to study these processes. Initial experiments using organotin derivatives as the organometallic nucleophile highlighted the problems of selectivity and the forcing conditions needed in the attempted transfer of a benzyl group from the tin to the palladium catalyst. The compounds [8- (dimethylamino)-1-naphthyl]methyldiphenyltin (60) and [2-((dimethylamino)methyl) phenyl]methyldiphenyltin (70) were prepared and their reactivity in the palladium catalysed cross-coupling with 2-furoyl chloride, to give 2-benzoylfuran, was investigated. These molecules were found to undergo facilitated transfer of a phenyl group compared to transfer from control molecules. The effect was tested and attributed to the internal nucleophilic attack at the tin atom by the lone pair on the nitrogen atom. The compound [2- ((dimethylamino)methyl)-3-trimethylsilylphenyl]methyldiphenyltin (79) was prepared to test the effects of steric buttressing within the molecule, but was found to be of the same order of magnitude of reactivity as (60) and (70). All three molecules showed a reactivity of at least an order of magnitude greater than control compounds. The effect did not prove applicable to the transfer of a benzyl group or in other coupling reactions. The effect of palladium ligation was tested and the ligand triphenyl arsine found to increase the rate of the coupling reaction. The two facilitating processes were found to work in a co-operative fashion, giving a rate enhancement of ca. one hundredfold over control reactions. The nickel catalysed cross-coupling of α-substituted sp³ hybridised Grignard reagents with allylic esters was attempted, but proved unsuccessful. Stoichiometric reactions with nickel complexes were also found to be unsatisfactory in yielding coupled products. The synthesis of α-substituted diorganozinc reagents was attempted, but furnished only homocoupled products. The reaction of dibenzylzinc with aldehydes was found to proceed in the absence of catalyst, highlighting the reactivity of a benzylzinc moiety.

547

Oxidation and reduction properties of iron-containing oxides.

Ayub, Ibrar.

January 2001

Thesis (Ph. D.)--Open University. BLDSC no. DXN049333.

Palladium complexes of aromatic amide-derived phosphines and application for synthesis of biaryls, nitrogen heterocycles, and benzo[b]furans /

Yue, Congyong.

January 2009

Includes bibliographical references (p. 205-218).

Sintering and reactivity of model oxide-supported catalysts : Pt/ZnO(000-1)-O and Pd/[alpha]-Al₂O₃(0001) /

Ngo, Lien Thuy.

January 2004

Thesis (Ph. D.)--University of Washington, 2004. / Vita. Includes bibliographical references (leaves 100-106).

Development of amide-derived P,O-ligands for Suzuki cross-coupling of aryl chlorides and the asymmetric version /

Zhang, Ye.

January 2005

Thesis (Ph.D.)--Hong Kong University of Science and Technology, 2005. / Includes bibliographical references (leaves 165-180). Also available in electronic version.

Synthesis and application of bidentate iminophosphine ligands in palladium-catalysed reactions.

Van Niekerk, Marie

19 May 2008

The duel objective of the research described in this dissertation, was the optimisation of reaction conditions for various palladium(0)-catalysed Heck-type reactions, and the development and application of bidentate iminophosphine ligands for some of these reactions. The efficiency of Heck and Heck-type reactions was evaluated by comparison of various parameters, e.g. solvent, palladium salt, reaction temperature and ligands for these palladium salts. In most cases, DMF was used as solvent, and palladium acetate served as a source of catalyst. Reactions were mostly carried out at 110 ºC, and triphenylposphine was used as the bench mark monodentate ligand, while 1,3-bis(diphenylphos-phino)propane (dppp) was applied as a bench mark for the performance of bidentate ligands. Apart from the Heck reaction between aryl halides and olefins, palladium-catalysed esterification reactions, transmetallation reactions and intramolecular reactions were investigated. A series of iminophosphine ligands was synthesised via the condensation of 2-(diphenylphosphino)benzaldehyde with primary amines. Although these ligands are thermally stable, they are extremely susceptible towards oxidation. This problem of oxidation, together with their unstability on silica, led us to the development of specialised techniques to isolate and purify the ligands. Distillation of these ligands under vacuum, together with the simultaneous subjection of the distillation apparatus to an inert argon atmosphere, resulted in the isolation of pure, unoxidised iminophosphine ligands. Application of the synthesised iminophosphine ligands to the optimised Heck reaction, indicated that these ligands were catalytically active. A series of Heck reactions employing different aryl halides, was chosen to test the efficiency of the newly synthesised ligands. In the cases of iodobenzene and o-nitroiodobenzene, similar results were obtained for triphenylphosphine, the iminophosphine ligands, and dppp. However, in the case of p-bromobenzonitrile, where the oxidative addition of palladium to the C-Br bond is slower than for corresponding C-I bonds, the efficiency of the iminophosphine ligands could clearly be seen in the higher yields that were obtained in comparison to the bench mark ligands. Further development of bidentate P-N ligands with different electronic characteristics, and application of these ligands with palladium and other transition metals for catalysis, is a field of research that should not be left unexpored. / Prof. D.B.G. Williams

synthesis

organometallic compounds

palladium catalysts

ligands

chemical reactions

Template synthesis of palladium and platinum nanoparticles by dendrimer and reverse microemulsions for the catalytic evaluation on various reactions

Noh, Ji-Hyang

09 November 2015

PhD. (Chemistry) / Well-defined palladium and platinum nanoparticles were synthesized by two template methods, namely dendrimer template and reverse microemulsions. For dendrimer template, three dendrimers, generation 4, 5, and 6 hydroxyl terminated poly(amidoamine) dendrimers (PAMAM), G4-OH, G5-OH, and G6-OH, were used as stabilizing agent, with PdCl4 2- or PtCl4 2- metal ions to dendrimer ratio of 40, 80, and 160, respectively. For reverse microemulsions, we employed water/AOT surfactant/isooctane system with water to surfactant ratios (ω0) of 5, 10, and 13, capped with thiol, to produce Pd and Pt nanoparticles. A total of twelve catalysts were characterized by techniques such as UV-Vis spectroscopy, TEM, EDX, and p-XRD. In the dendrimer template method, the synthesis of Pd and Pt nanoparticles in lower concentrations produced smaller sizes with narrower size distributions (2.02 ± 0.45 ~ 2.35 ± 0.58 nm Pd nanoparticles, 1.90 ± 0.44 nm ~ 2.48 ± 0.60 nm Pt nanoparticles) compared to those in higher concentrations (2.74 ± 0.44 ~ 3.32 ± 0.86 nm Pd nanoparticles, 2.81 ± 0.70 nm ~ 3.03 ± 0.47 nm Pt nanoparticles). In the case of thiol-capped Pd and Pt nanoparticles by reverse microemulsions, the range of average particle sizes were 3.47 - 7.51 nm and 3.51 - 4.23 nm for Pd and Pt nanoparticles, respectively. This indicated that a wider size regime was obtained by the reverse microemulsion method as compared to the dendrimer template method. Overall, smaller sizes with narrower size distributions were achieved by using the dendrimer-templated synthetic method rather than reverse microemulsions for both Pd and Pt nanoparticles.

Palladium catalysts

Chemical reactors

Chemistry, Inorganic

Nanostructured materials

Platinum

Catalysis

The structure elucidation and synthesis of selected natural products

Marais, Wilhelmina

04 September 2012

D.Phil. / The objective of the research described in the first part of this thesis was to develop a general method utilising palladium catalysed reactions for the synthesis of the anti-cancer compound, lavendamycin and analogs thereof. Therefore, the development of a general route to synthetic euivalents of the lavendamycin AB quinoline system, 2-hydroxyquinolines, with potential for coupling to the CDE or CD moiety, was addressed. The first protocol for the synthesis of 2-hydroxyquinolines invloved to the use of appropriately substituted o-nitrophenyltriflates (readily prepared from phenols) in a Heck reaction under neutral conditions followed by a one-pot reduction and cyclisation step. The synthetic potential of such an approach was demonstrated by the preparation of a suitable lavendamycin AB synthon from commecially avalaible guiacol. A second general strategy towards the synthesis of the AB synthon utilising a performed ring system commecially available 8-hydroxyquinoline has been successfully developed. This approach requiring the introduction of a suitable leaving group in the 2-position involved the following sequence of reactions: protection of 8-hydroxyl group N-oxidation, and a rearrangement step. This methodology yielded five different key intermediates all possessing suitable functionality in the 2 position which would allow further cross-coupling to an appropriate CDE ring equivalent.

Organic compounds -- Synthesis

Palladium catalysts

Medicinal plants -- South Africa

Metabolites

Kinetics of the Hydrodechlorination Reaction of Chlorinated Compounds on Palladium Catalysts

Chen, Nan

23 August 2003

" Hydrodechlorination is the reaction of a chlorinated organic compound (R-Cl) with hydrogen to form a carbon-hydrogen bond and HCl: R-Cl + H2 = R-H + HCl. This reaction is used in refrigerant manufacturing, industrial by-product reclamation and waste management. These practical applications require in-depth understanding of hydrodechlorination reaction. In this research work, we studied four families of chlorinated compounds; CF3CF3-xClx(x=1-3), CH4-xClx (x=1-4), CF4-xClx (x=1-4) and dichloropropanes (1,1-, 1,2-, 1,3-, 2,2-), on supported palladium catalysts to create a theory capable of predicting the hydrodechlorination rate on chlorinated compounds and to explore the reaction mechanism. A possible set of elementary reaction steps of hydrodechlorination reaction was proposed from our kinetics study of all these compounds. In this set of reaction steps, the irreversible scission of the first C-Cl bond in a chlorinated compound was proposed to be the rate-determining step; gas phase H2 and HCl were suggested to be in equilibrium with surface H and Cl species; adsorbed Cl was assumed to be the most abundant surface intermediate. The overall rate of hydrodechlorination reaction could be derived from these reaction steps as r=k'[R-Cl]/(1+K'[HCl]/[H2]0.5). In this rate equation, k'is the product of the adsorption equilibrium constant of the chlorinated compound on catalyst surface times the rate constant for the scission of the first C-Cl bond scission step, and K'is the square root of the equilibrium constant for the equilibrium between H2, HCl and their corresponding surface species: 2HCl + 2* = H2 + 2Cl*. The hydrodechlorination reaction of CF3CFCl2 was performed in the presence of H37Cl to study the reversibility of C-Cl bond scission, and the removal of the first Cl atom from CF3CFCl2 was found to be an irreversible step. Hydrodechlorination experiments of CF3CFCl2 with D2 and HCl mixture revealed that D2 and HCl were in equilibrium with surface adsorbed hydrogen and chlorine during reaction. The forward rate and reverse rate of this equilibrium were at least 400 times higher than the overall hydrodechlorination rate. This result supported the assumption of equilibrium for 2HCl + 2* = H2 + 2Cl*. Additionally, the activation energy for the rate determining step was extracted from hydrodechlorination reaction kinetics results of CH4-xClx (x=1-4), CF4-xClx (x=1-4) and dichloropropanes (1,1-, 1,2-, 1,3-, 2,2-) compounds. It was found that for each of the series compounds, a linear relationship existed between C-Cl bond scission activation energy and gas phase C-Cl bond strength. This observation corroborates our assumption that the removal of the first Cl atom from a chlorinated compound is the rate-determining step in the hydrodechlorination reaction. Thus, all kinetic and isotope experimental results obtained from this study are consistent with the proposed reaction steps for the chlorinated compounds tested. This set of reaction steps can also be used to predict the hydrodechlorination reaction rate of a chlorinated compound, once its gas phase C-Cl bond energy is calculated and the turnover rate of a reference chlorinated compound with similar structure is known. Some work has been done to study hydrodechlorination reaction steps and reaction intermediates beyond the rate-limiting step. Isotope tracing experiments with D2 indicated that CH3-, CH2- groups adjacent to a C-Cl bond could undergo deuterium exchange. The study of reactions steps using ab initio methods, including calculation of rate constants, is also under way. Calculations for the CH4-xClx (x=1-4) family showed that the heat of adsorption and C-Cl bond dissociation energy on a Pd surface were linearly related to their gas phase C-Cl bond strength."

chlorinated compounds

reaction steps

reaction kinetics

hydrodechlorination

Palladium catalysts

Palladium catalysts

Organochlorine compounds

Reaction mechanisms in organic chemistry

Hydrodechlorination