[PDF] Mechanistic Studies On Palladium Catalyzed Carbon Nitrogen Bond Forming Reactions eBook

Author : Liane May Klingensmith
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Page : 138 pages
File Size : 42,71 MB
Release : 2005
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Precatalyst species present in a solution of Pd2(dba)3 and Xantphos were identified as Pd(Xantphos)(dba) and Pd(Xantphos)2 by use of 31p NMR and independent syntheses. Pd(Xantphos)2 was found to form at high ligand concentrations. To determine whether the formation of this species affected reaction rates, reaction calorimetry was used to explore the rate of the palladium-catalyzed coupling of 4-t-butylbromobenzene and morpholine using the ligand Xantphos at varying palladium to ligand ratios. It was found that catalyst activity is dramatically dependent on the concentration of ligand relative to palladium, due to formation of Pd(Xantphos)2. Two plausible hypotheses for the low activity of Pd(Xantphos)2 as a precatalyst are (1) a slow rate of dissociation of a ligand from the bis-ligated species, and (2) the high degree of insolubility of Pd(Xantphos)2. Magnetization transfer experiments were used to probe the rate of dissociation of ligand for the bis-ligated species, and reaction calorimetry experiments were performed using the more soluble t-butylXantphos in comparison to Xantphos to determine whether the insolubility of' Pd(Xantphos)2 causes it to have relatively low activity. It was found that solubility is not the main cause for the low activity of Pd(Xantphos)2, and evidence was given to support the hypothesis that low activity results from the slow dissociation of a ligand from the bis-ligated species.

Author : Eric R. Strieter
Publisher :
Page : 330 pages
File Size : 15,12 MB
Release : 2005
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(Cont.) A systematic mechanistic analysis of Pd(OAc)2/ monophosphino- biaryl-catalyzed C-N bond forming reactions with aryl chlorides has been performed. The results provide insights into the relationship between the steady-state concentration of active Pd and the size and substitution pattern of the monophosphinobiaryl ligands. These insights into the nature of catalyst activation help highlight the importance of establishing a high concentration of active catalyst. The catalyst derived from the bulkiest ligand in the series, the tri-i-propyl ligand 13, exhibits both accelerated rate and the increased stability required for practical application of this reaction.

Author : Alexandra Eve Strom
Publisher :
Page : 323 pages
File Size : 35,58 MB
Release : 2015
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The following dissertation discusses reactions for the formation of carbon-nitrogen bonds mediated by organotransition metal reagents and catalysts. Chapter 1 presents a synthetic method for the formal hydroamination of unactivated alkenes to form anti-Markovnikov primary and secondary amine products. This transformation is accomplished through the hydrozirconation and subsequent amination of alkenes. The method is then applied to the reaction of complex molecules to emphasize the functional group tolerance of these reactions. Chapter 2 of this thesis comprises the synthesis and evaluation of a series of rhodium-phosphine hydroamination catalysts. These complexes are evaluated in a series of catalytic intramolecular Markovnikov hydroamination reactions. The mechanism of hydroamination catalyzed by the rhodium(I) complexes in this study was examined computationally, and the turnover-limiting step was elucidated. The difference in reactivity of electron-rich and electron-poor catalysts was compared to the computational results of a computational ligand screen, and it was found that the computational analysis of reaction intermediates overestimated the reactivity of electron-poor catalysts. The analysis of the catalysts in this study was expanded to include the binding preference of each ligand, compared to the unsubstituted ligand, which corrects for the disparity between observed reactivity and the calculated overall reaction barrier for electron-poor ligands. The ligand-binding preferences for new ligand structures were calculated, and it was found that ligands that were predicted to bind strongly to rhodium had improved reactivity in catalytic reactions. Chapter 3 discusses the mechanistic study of the palladium-catalyzed aminocarbonylation of aryl halides with ammonia and CO to form primary benzamides. Conditions for reactions of aryl bromides, chlorides, and iodides are described, and the mechanism of reactions of aryl bromides was studied. The kinetic order in the concentration of aryl bromide was found to be first order, and the order in the pressure of CO was found to be inverse first order. These studies were complemented by DFT calculations on the mechanism of oxidative addition of aryl bromides. The products of oxidative addition, aroyl bromide palladium intermediates, were reacted with ammonia in the presence of additives to gain insight into the mechanism of release of product. The overall dependence on the rate of the catalytic reaction was found to be insensitive to excess ammonia, indicating that the overall turnover-limiting step of the reaction is during the oxidative addition step.

Author : Pedro Luis Arrechea
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Page : 253 pages
File Size : 11,94 MB
Release : 2016
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Mechanistic studies on the palladium catalyzed C-N bond-forming reaction were carried out to generate a more complete understanding of the catalytic cycle. To understand this reaction, several kinetic studies employing simple aryl halide and amine coupling partners were performed to elucidate unknown reaction pathways. Chapter 1. The resting state for the palladium catalyzed cross-coupling of various diarylamines and aryl halides is found to be the diphenylamido complex. Kinetic studies of the catalytic reaction are used to generate an Eyring plot. Hammett studies were performed for both the aryl halide and diarylamine coupling partners. The rates of reductive elimination for catalysts based on the biaryl ligands XPhos, CyJohnPhos, CPhos, BrettPhos, RuPhos, and SPhos were evaluated. Analogues of SPhos demonstrated that electron-donation of the lower aryl group is key to the stability of the amido complex in accordance with theoretical calculations. The methoxy substituent at the C3 position is demonstrated to retard the overall rate of reductive elimination for a RuPhos-BrettPhos hybrid ligand. These studies demonstrate that reductive elimination is likely not a problematic step for C-N cross-couplings. Chapter 2. Kinetic experiments demonstrated an inverse dependence on the concentration of both amine and aryl halide coupling partners. These observations are demonstrated to be valid for several amine classes, aryl halides, and biaryl ligands. Some work is done to demonstrate mechanistic overlap with other bidentate ligands. Based on these studies, a simplified reaction network for oxidative addition is proposed which reproduces key features of the experimental system.

Author : Rebecca Green
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Page : 183 pages
File Size : 23,47 MB
Release : 2016
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The following dissertation discusses the development of a nickel catalyst for the synthesis of Csp2-Csp bonds in addition to the development and mechanistic studies of nickel and palladium catalysts for the synthesis of Csp2-N bonds. The first chapter is a review of the cross-coupling reactions discussed in this dissertation. Nickel and palladium will be compared with respect to physical properties and reactivity differences. The challenges associated with nickel-catalyzed cross coupling will be illustrated, while drawing analogies to analogous palladium-catalyzed reactions. The literature background for the synthesis of Csp2-Csp bonds, catalyzed by palladium and palladium/copper catalytic systems, will be reviewed, while highlighting the challenges and limitations of the field. The field of Csp2-N bond-forming reactions will be examined, as the differences in reactivity between nickel and palladium will be emphasized. Chapter 2 discusses our efforts towards the development of a nickel catalyst for the development of a Csp2-Csp bond forming reaction, performed in the absence of a copper co-catalyst. Chapter 3 describes the development of a single-component nickel complex that catalyzes the coupling of aryl chlorides with primary alkylamines. A series of mechanistic experiments, including synthesis of catalytic intermediates and kinetic experiments, were performed to elucidate the mechanism of the reaction. Chapter 4 discusses our report the palladium-catalyzed coupling of aryl halides withammonia and gaseous amines as their ammonium salts. A difference in selectivity between reactions of aryl chlorides and aryl bromides was discovered and investigated. Chapter 5 describes the development of a single-component nickel catalyst for the coupling of aryl chlorides with ammonia and ammonium sulfate to form the corresponding primary arylamines. The application of ammonium salts was extended to the coupling of gaseous amines, such as methylamine and ethylamine, which were subjected to the reaction conditions as their hydrochloride salt.

Author : Rachel Elizabeth Tundel
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Page : 136 pages
File Size : 44,48 MB
Release : 2006
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Chapter 1. Microwave-assisted, palladium-catalyzed C-N bond-forming reactions with aryl/heteroaryl nonaflates/halides and amines using the soluble amine bases DBU (1,8-diazabicyclo[5.4.0]undec-7-ene) or MTBD (7-methyl-1,5,7-triazabicyclo[4.4.0]dec-5-ene) and a catalyst system consisting of Pd2dba3 and ligands (XantPhos, 2-dicylcohexylphosphino-2',4',6'-triisopropyl-1,1 '-biphenyl (XPhos) and 2-di-tert-butylphosphino-2',4',6'-triisopropyl-1, '-biphenyl) resulted in good to excellent yields of arylamines in short reaction times. Chapter 2. Using a catalyst comprised of the bulky, electron-rich monophosphine ligand di-tert-Butyl XPhos (2-di-tert-butylphosphino-2',4',6'-triisopropyl-1,1'-biphenyl) and Pd2dba3 with sodium tert-butoxide as the base, amino heterocycles were coupled successfully with aryl/heteroaryl halides in moderate to excellent yields.

Author : Jay Kochi
Publisher : Elsevier
Page : 642 pages
File Size : 48,33 MB
Release : 2012-12-02
Category : Science
ISBN : 0323144101

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Organometallic Mechanisms and Catalysis: The Role of Reactive Intermediates in Organic Processes covers the mechanistic delineation of organometallic chemistry and catalysis. This book is organized into three parts encompassing 18 chapters. The first part describes first the oxidation-reduction process of organometals, followed by discussions on the catalytic reactions of peroxides, metal-catalyzed addition to olefins, and reduction of organic halides. This part also explores other reactions involving transition metal carbonyls and metal-catalyzed reactions of aromatic diazonium salts. The second part deals with some chemical aspects of organometals, such as their stability, thermochemistry, decomposition, hemolytic pathways, and the formation of carbon-carbon bonds. The third part examines the charge transfer processes and interactions of organometals with electron acceptors. This part further looks into the cleavage and insertion reactions of organometals with electrophiles, as well as the electrophilic and electron transfer mechanisms of organometals. Organic and inorganic chemists, teachers, and students will greatly benefit from this book.

Author : Louis-Charles Campeau
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Page : 0 pages
File Size : 49,54 MB
Release : 2008
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The biaryl core has been identified by medicinal chemists as a privileged structure in pharmaceutical compounds as it is found in 4.3% of all drugs. For over a century, synthetic chemists have sought new methods for their preparation. Breakthroughs in synthetic catalytic methodology over the past thirty years gave rise to now routine reactions such as the Suzuki and Stille couplings. Unfortunately, the need for pre-activation of both coupling partners makes for wasteful installation and subsequent removal of activating agents. Direct arylation reactions are attractive alternatives to traditional cross-coupling methods, as one of the pre-activated partners is replaced with a simple arene. The organometallic coupling partner is typically replaced as it is the most difficult to prepare. Although the advantages of this approach have made it a popular research topic for more than twenty-five years, no general catalysts exist for this transformation, and in a lot of cases reactivity remains a challenge. This thesis will outline our work in this area of research. First, our efforts toward the development of a general catalyst for the intramolecular direct arylation of aryl halides with simple arenes will be presented. These studies led to the development of three new catalysts for this transformation, affording a process general for aryl chlorides, bromides and iodides. Additionally, mechanistic studies performed on this system have brought to the forefront the concerted metallation-deprotonation mechanistic model for direct arylation. Ultimately, these studies led to the first non-directed intermolecular direct arylation of a simple arene. In a second section, efforts toward the inclusion of pi-deficient heteocycles as a substrate class in direct arylation will be outlined. These studies led to the development of a novel cross-coupling reaction of azine N-oxides with aryl halides. Greater mechanistic understanding, made possible through the use of computational tools, was crucial in extending this methodology to azole N-oxides. Finally, the development of novel direct functionalization reactions with picoline derivatives is described. These substrates are among the first to be suitable for catalyst controlled site-selective functionalization of a sp2 or sp3 C-H bond.