Catalytic Stereoselective 1,3-Enyne Carboboration, Hydroalkynylation, and Hydrothiolation Reactions:

Wang, Ziyong

January 2023

Thesis advisor: Shih-Yuan Liu / Thesis advisor: Amir H. Hoveyda / Chapter 1. Senphos–Palladium-Catalyzed cis-Carboboration of Internal 1,3-Enynes with Carbon–Bound Boron Enolates: Reaction Development and Mechanistic Analysis. A new family of carbon-bound boron enolates (C–boron enolates) that are created through a kinetically controlled halogen exchange process between B–chlorocatecholborane and silylketene acetals is presented. These C–boron enolates are demonstrated to activate 1,3-enynes substrates in the presence of a Senphos-Pd complex to achieve carboboration reaction of an alkyne unit. This carboboration reaction produced highly substituted dienyl boron building blocks in high site-, regio-, and diastereoselectivity. A combined experimental and computational study of this carboboration reaction by Density-Functional Theory (DFT) calculations, 31P NMR study, kinetic study, Hammett analysis and Arrhenius/Eyring analysis will also be described. Mechanistic study supports a syn outer-sphere oxidative addition mechanism featuring a Pd-π-allyl intermediate followed by coordination-assisted rearrangement instead of the conventional inner-sphere β-migratory insertion mechanism. Chapter 2. trans-Hydroalkynylation of Internal 1,3-Enynes Enabled by Cooperative Catalysis. A trans-hydroalkynylation reaction of internal 1,3-enynes enabled by a cooperative catalysis system that comprises of Senphos–Pd complex, tris(pentafluorophenyl)borane, copper(I) bromide, and 2,2,6,6-tetramethylpiperidine, is described. The tris(pentafluorophenyl)borane as Lewis acid catalyst is shown to promote the reaction involving the emerging outer-sphere oxidative reaction step. This hydroalkynylation reaction affords the cross-conjugated dieneynes that serve as versatile synthons for organic synthesis. The photophysical properties of these cross-conjugated dieneynes depend on the position of electron donor/acceptor substituents along the conjugation path, as characterized by UV–vis absorption and emissions spectroscopy. Chapter 3. Senphos–Palladium/B(C6F5)3-Catalyzed trans-Hydrothiolation of 1,3-Enynes: Reaction Development and Mechanistic Analysis. A trans-hydrothiolation reaction of 1,3-enynes enabled by a cooperative catalysis system that comprises of Senphos–Pd complex and tris(pentafluorophenyl)borane is detailed. The tris(pentafluorophenyl)borane is shown to alter the reaction pathway, leading to a trans-addition product over cis-addition one. Experimental mechanistic study that includes 31P NMR, kinetic study, kinetic isotope effect (KIE) study, Hammett analysis, is consistent with a cooperative activation mechanism that features an outer-sphere protonation step. / Thesis (PhD) — Boston College, 2023. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

cis-Carboboration

Cooperative catalysis

Mechanistic analysis

Senphos-Pd complex

trans-hydroalkynylation

trans-hydrothiolation

Metal complex catalysed C-X (X = S, O and N) bond formation

Vuong, Khuong Quoc, Chemistry, Faculty of Science, UNSW

January 2006

This thesis describes the catalysed addition of X-H bonds (X = S, O and N) to alkynes using a range of novel rhodium(I) and iridium(I) complexes containing hybrid bidentate phosphine-pyrazolyl, phosphine-imidazolyl and phosphine-N heterocyclic carbene (NHC) donor ligands. The synthesis of novel bidentate phosphine-pyrazolyl, phosphine-imidazolyl (P-N) and phosphine-NHC (PC) donor ligands and their cationic and neutral rhodium(I) and iridium(I) complexes [M(P N)(COD)]BPh4, [M(PC)(COD)]BPh4, [Ir(P-N)(CO)2]BPh4 and [M(P-N)(CO)Cl] were successfully performed. An unusual five coordinate iridium complex with phosphine-NHC ligands [Ir(PC)(COD)(CO)]BPh4 was also obtained. Seventeen single crystal X-ray structures of these new complexes were determined. A range of these novel rhodium and iridium complexes were effective as catalysts for the addition of thiophenol to a variety of alkynes. Iridium complexes were more effective than rhodium analogues. Cationic complexes were more effective than neutral complexes. Complexes with hybrid phosphine-nitrogen donor were more effective than complexes containing bidentate nitrogen donor ligands. An atom-economical, efficient method for the synthesis of cyclic acetals and bicyclic O,O-acetals was successfully developed based on the catalysed hydroalkoxylation. Readily prepared terminal and non-terminal alkyne diols were cyclised into bicyclic O,O-acetals in quantitative conversions in most cases. The efficiency of a range of rhodium and iridium complexes containing bidentate P-N and PC donor ligands as catalysts for the cyclisation of 4-pentyn-1-amine to 2-methyl-1-pyrroline varied significantly. The cationic iridium complexes with the bidentate phosphine-pyrazolyl ligands, [Ir(R2PyP)(COD)]BPh4 (2.39-2.42) were extremely efficient as catalysts for this transformation. Increasing the size of the substituent on or adjacent to the donor led to improvement in catalytic activity of the corresponding metal complexes. The mechanism of the catalysed hydroalkoxylation was proposed to proceed by the initial activation of the alkyne via ?? coordination to the metal centre. The ?? binding of both aliphatic and aromatic alkynes to [Ir(PyP)(CO)2]BPh4 (2.44) was observed by low temperature NMR and no reaction between 2.44 and alcohols was observed. In contrast, the facility in which thiol and amine oxidatively added to 2.44 led the proposal that in the hydrothiolation and hydroamination reaction, the catalytic cycle commences with the activation of the X-H bond (X = S, N) by an oxidative addition process.

homegeneous catalysis

hybrid ligands

P-N ligands

NHC ligands

hydroamination

hydroalkoxylation

hydrothiolation

spiroketals

rhodium catalysts

iridium catalysts

metal complexes

alkynes

Metal complex catalysed C-X (X = S, O and N) bond formation

Vuong, Khuong Quoc, Chemistry, Faculty of Science, UNSW

January 2006

This thesis describes the catalysed addition of X-H bonds (X = S, O and N) to alkynes using a range of novel rhodium(I) and iridium(I) complexes containing hybrid bidentate phosphine-pyrazolyl, phosphine-imidazolyl and phosphine-N heterocyclic carbene (NHC) donor ligands. The synthesis of novel bidentate phosphine-pyrazolyl, phosphine-imidazolyl (P-N) and phosphine-NHC (PC) donor ligands and their cationic and neutral rhodium(I) and iridium(I) complexes [M(P N)(COD)]BPh4, [M(PC)(COD)]BPh4, [Ir(P-N)(CO)2]BPh4 and [M(P-N)(CO)Cl] were successfully performed. An unusual five coordinate iridium complex with phosphine-NHC ligands [Ir(PC)(COD)(CO)]BPh4 was also obtained. Seventeen single crystal X-ray structures of these new complexes were determined. A range of these novel rhodium and iridium complexes were effective as catalysts for the addition of thiophenol to a variety of alkynes. Iridium complexes were more effective than rhodium analogues. Cationic complexes were more effective than neutral complexes. Complexes with hybrid phosphine-nitrogen donor were more effective than complexes containing bidentate nitrogen donor ligands. An atom-economical, efficient method for the synthesis of cyclic acetals and bicyclic O,O-acetals was successfully developed based on the catalysed hydroalkoxylation. Readily prepared terminal and non-terminal alkyne diols were cyclised into bicyclic O,O-acetals in quantitative conversions in most cases. The efficiency of a range of rhodium and iridium complexes containing bidentate P-N and PC donor ligands as catalysts for the cyclisation of 4-pentyn-1-amine to 2-methyl-1-pyrroline varied significantly. The cationic iridium complexes with the bidentate phosphine-pyrazolyl ligands, [Ir(R2PyP)(COD)]BPh4 (2.39-2.42) were extremely efficient as catalysts for this transformation. Increasing the size of the substituent on or adjacent to the donor led to improvement in catalytic activity of the corresponding metal complexes. The mechanism of the catalysed hydroalkoxylation was proposed to proceed by the initial activation of the alkyne via ?? coordination to the metal centre. The ?? binding of both aliphatic and aromatic alkynes to [Ir(PyP)(CO)2]BPh4 (2.44) was observed by low temperature NMR and no reaction between 2.44 and alcohols was observed. In contrast, the facility in which thiol and amine oxidatively added to 2.44 led the proposal that in the hydrothiolation and hydroamination reaction, the catalytic cycle commences with the activation of the X-H bond (X = S, N) by an oxidative addition process.

homegeneous catalysis

hybrid ligands

P-N ligands

NHC ligands

hydroamination

hydroalkoxylation

hydrothiolation

spiroketals

rhodium catalysts

iridium catalysts

metal complexes

alkynes

Hydroamination and Hydrothiolation Catalyzed by 3-Iminophosphine Palladium Complexes

Thakuri, Rajendr Singh

January 2020

No description available.

Chemistry

Organic Chemistry

dimesityl phosphine

lithium dimesitylphosphide

steric phosphine

3-iminophosphine ligand

Palladium Catalyst

hydroamination

allenes

allylamine

isomerization

amines

kinetic product

thermodynamic product

hydrothiolation

dithioacetal