Mononuclear and multinuclear salicylaldimine metal complexes as catalysts precursors in the oxidation of phenol and cyclohexene

Van Wyk, Juanita Lizélle

January 2009

Philosophiae Doctor - PhD / In this thesis typical homogeneous and dendritic immobilized catalysts derived from salicylaldimines were investigated as catalysts for the oxidation of hydrocarbons using hydrogen peroxide as oxidant under aerobic conditions. This research work thus describes the synthesis of several new N-(aryl)salicylaldimines as well as peripheral functionalised salicylaldimine poly(propyleneimine) dendrimers. The dendritic ligands were obtained by modifying the peripheral groups of Generation 1 and Generation 2 poly(propyleneimine) dendrimer, (DAB-(NH2)n) which are commercially available. Both types of ligands were utilized to synthesize Cu(II) and Co(II) complexes using appropriate acetate salts. The ligands systems and metal complexes prepared were fully characterized using a range of physical techniques. The Cu(II) and Co(II) complexes were evaluated as catalysts for the oxidation of phenol and cyclohexene using hydrogen peroxide as oxidant under an oxygen atmosphere. The catalytic oxidation of phenol to the dihydroxybenzenes, catechol (CT) and hydroquinone (HQ), was investigated in aqueous media at various pH values. All the complexes investigated were active for the hydroxylation process producing CT as major product. The pH of the reaction medium was found to have much more of an influence on the activity and product selectivity of the Co(II) complexes as compared to the case for the Cu(II) complexes. All the catalysts investigated were also found to exhibit good activity for the oxidation of cyclohexene producing predominantly the allylic oxidation products 2-cyclohexene-1-one and 2-cyclohexene-1-ol. However the formation of the epoxide, cyclohexene oxide was also observed as minor product or in trace quantities. It was found that the cobalt catalysts produced 2-cyclohexene-1-one as major product, however higher levels of 2-cyclohexene- 1-ol was produced by all catalysts in catalytic runs where the oxidant to substrate ratio was reduced and when the metal loading was increased. In the case of the copper catalysts 2- cyclohexene-1-ol was produce in slightly higher levels than 2-cyclohexene-1-one.

Catalysts precursors

Oxidation of phenol

Development of Calcium and Palladium Catalysts for the Formation of Carbon-Carbon and Carbon-Heteroatom Bonds

Kunchithapatham, Kamala

25 June 2012

No description available.

Chemistry

catalysis

calcium

salicylaldimine

hydroamination

cross-coupling

thioesters

oxazoles

C-H activation

terminal olefins

vinylsilanes

Synthesis of 1,3,5-triaza-7-phosphaadamantane (PTA) and 3,7-diacetyl-1,3,7-triaza-5-phosphabicyclo[3.3.1]nonane (DAPTA) complexes and the development of chromium salen catalysts for the copolymerization of CO2 and epoxides

Ortiz, Cesar Gabriel

30 September 2004

Two main areas are considered in this manuscript. The first describes the synthesis of group 10 metal complexes incorporating the water-soluble 1,3,5-triaza-7-phosphaadamantane (PTA) ligand and the second deals with the preparation of Cr(salen)X catalysts for the copolymerization of CO2 and epoxides. In the first topic, the synthesis of nickel(II) and palladium(II) salicylaldiminato complexes incorporating PTA has been achieved employing two preparative routes. Upon reacting the original ethylene polymerization catalyst developed by Grubbs and coworkers (Organometallics, 1998, 17, 3149), (salicylaldiminato)Ni(Ph)PPh3, with PTA using a homogeneous methanol/toluene solvent system resulted in the formation of the PTA analogs in good yields. Alternatively, complexes of this type may be synthesized via a direct approach utilizing (TMEDA)M(CH3)2 (M = Ni, Pd), the corresponding salicylaldimine, and PTA. Polymerization reactions were attempted using the nickel-PTA complexes in a biphasic toluene/water mixture in an effort to initiate ethylene polymerization by trapping the dissociated phosphine ligand in the water layer, thereby, eliminating the need for a phosphine scavenger. Unfortunately, because of the strong binding ability of the small, donating phosphine (PTA) as compared to PPh3, dissociation did not occur at a temperature where the complexes are not subjected to decomposition. Additionally, the unexplored PTA derivative, 3,7-diacetyl-1,3,7-triaza-5-phosphabicyclo[3.3.1]nonane (DAPTA), prepared by the literature procedure, was fully characterized by NMR and X-ray analysis. DAPTA is found be similar to its parent (PTA) in coordination mode and binding strength, as supported by its representative group 6 and group 10 complexes The second main topic involves the copolymerization of CO2 and epoxides (i.e., cyclohexene oxide (CHO)) for the formation of polycarbonate using Cr(salen)X (X = Br, OPh) catalysts with one equivalent of PR3 as the co-catalyst. The use of these catalysts and cocatalysts results in the most active chromium-based catalytic systems to date. The . hr-1highest activities observed are on the order of 109 mol CHO consumed . mol Cr-1 using PCy3 as the co-catalyst, and is clearly seen in the in situ monitoring of copolymer formation. An advantage of these systems involves the lack of cyclic carbonate production and high CO2 incorporation (>99%) within the polymer.

CO2

Polycarbonate

Chromium

Water-Soluble Phosphines

PTA

DAPTA

Epoxide

Aqueous Organometallic Chemistry

Salen

Daco

Dach

Ethylene Polymerization

Salicylaldimine

Investigations into cyclopropanation and ethylene polymerization via salicylaldiminato copper (II) complexes

Boyd, Ramon Cornell

23 January 2007

Two distinct overall research objectives are in this Masters thesis. Very little relates the two chapters apart from the ligands. The first chapter addresses diastereoselective homogeneous copper catalyzed cyclopropanation reactions. Cyclopropanation of styrene and ethyl diazoacetate (EDA) is a standard test reaction for homogeneous catalysts. Sterically bulky salicylaldimine (SAL) ligands should select for the ethyl trans-2-phenylcyclopropanecarboxylate diastereomer. Steric bulk poorly influences trans:cis ratios. Salicylaldiminine ligands do not posses the correct symmetry to affect diastereoselectivity. The SAL ligand belongs to the Cs point group in the solid state. Other ligand motifs are more effective at altering the trans:cis ratios. The second chapter addresses the general route toward successful copper(II) ethylene polymerization catalysts. Catalytic activity of the copper(II) complexes is very low. Polymer chain growth from a copper catalyst is very unlikely. Copper-carbon bonds decompose by homolytic cleavage or C-H activation. Copper-alkyls and aryls readily decompose into brown colored oils and salts with different colors. Ligand transfer to trimethylaluminum (TMA) appears to explain low yield ethylene polymerization.

bulky

migratory insertion mechanism

coordination/insertion methodology

d-block metal

late transition metal

phenolic ring

coordination number

ketimine

precatalysts

ketimine nitrogen

bis(salicylaldiminato)copper(II)

ratio

cyclopropane

steric bulk

salicylaldiminato

TMA

salt

trimethylaluminum

aryl

oil

alkyl

copper-aryls

copper-alkyls

C-H activation

homolytic

homolytic cleavage

copper(II)

polymerization

ethylene

cis

trans

symmetry

diastereomer

salicylaldimine

SAL

EDA

ethyl diazoacetate

styrene

cyclopropanation

copper

diastereoselective

steric protection

stable

CH(SiMe3)2

intermediate

catalytic activity

associated TMA

free TMA

vacant coordination site

hydrolysis

Lewis acid

halogen

anionic

anionic ligand

donor ligand

monodentate anionic ligand

aluminum(III)

monodentate

polymer chain

polymer

chain

aluminum-carbon bond

bulky SAL ligand

open coordination site

first row transition metal

PE

paramagnetic

high molecular weight polyethylene

alkylate

methylaluminoxane

MAO

anionic ligands

arylate

aluminum carbon

aluminum carbon bond

beta-hydrogen elimination

beta hydrogen elimination

Aufbau reaction

Aufbau

neutral dialkyl aluminum

aluminum-alkyl

aluminum alkyl

copper(0)

Investigations into cyclopropanation and ethylene polymerization via salicylaldiminato copper (II) complexes

Boyd, Ramon Cornell

23 January 2007

Two distinct overall research objectives are in this Masters thesis. Very little relates the two chapters apart from the ligands. The first chapter addresses diastereoselective homogeneous copper catalyzed cyclopropanation reactions. Cyclopropanation of styrene and ethyl diazoacetate (EDA) is a standard test reaction for homogeneous catalysts. Sterically bulky salicylaldimine (SAL) ligands should select for the ethyl trans-2-phenylcyclopropanecarboxylate diastereomer. Steric bulk poorly influences trans:cis ratios. Salicylaldiminine ligands do not posses the correct symmetry to affect diastereoselectivity. The SAL ligand belongs to the Cs point group in the solid state. Other ligand motifs are more effective at altering the trans:cis ratios. The second chapter addresses the general route toward successful copper(II) ethylene polymerization catalysts. Catalytic activity of the copper(II) complexes is very low. Polymer chain growth from a copper catalyst is very unlikely. Copper-carbon bonds decompose by homolytic cleavage or C-H activation. Copper-alkyls and aryls readily decompose into brown colored oils and salts with different colors. Ligand transfer to trimethylaluminum (TMA) appears to explain low yield ethylene polymerization.

bulky

migratory insertion mechanism

coordination/insertion methodology

d-block metal

late transition metal

phenolic ring

coordination number

ketimine

precatalysts

ketimine nitrogen

bis(salicylaldiminato)copper(II)

ratio

cyclopropane

steric bulk

salicylaldiminato

TMA

salt

trimethylaluminum

aryl

oil

alkyl

copper-aryls

copper-alkyls

C-H activation

homolytic

homolytic cleavage

copper(II)

polymerization

ethylene

cis

trans

symmetry

diastereomer

salicylaldimine

SAL

EDA

ethyl diazoacetate

styrene

cyclopropanation

copper

diastereoselective

steric protection

stable

CH(SiMe3)2

intermediate

catalytic activity

associated TMA

free TMA

vacant coordination site

hydrolysis

Lewis acid

halogen

anionic

anionic ligand

donor ligand

monodentate anionic ligand

aluminum(III)

monodentate

polymer chain

polymer

chain

aluminum-carbon bond

bulky SAL ligand

open coordination site

first row transition metal

PE

paramagnetic

high molecular weight polyethylene

alkylate

methylaluminoxane

MAO

anionic ligands

arylate

aluminum carbon

aluminum carbon bond

beta-hydrogen elimination

beta hydrogen elimination

Aufbau reaction

Aufbau

neutral dialkyl aluminum

aluminum-alkyl

aluminum alkyl

copper(0)