Search results for "phenoxyimine"

showing 3 items of 3 documents

Theoretical study of isomerism in phenoxyimine-based precursors of coordinative olefin polymerization catalysts

2010

Precursors of post-metallocene olefin polymerization catalysts, unlike their predecessors, are usually octahedral transition metal complexes with multidentate ligands. Such ligands may wrap around the central atom in many ways, thus yielding several isomeric species. For a wide range of phenoxyimine (FI) ligands with different substituents, all the theoretically predicted diastereomers of group 4 and 5 complexes are available synthetically. However, only one of the isomers is usually preferred, and this is determined by the nature of the substituents in the FI ligand. The origin and mechanism of such preference has not been completely elucidated. We attempted to describe it quantitatively o…

DenticitySchiff baseLigandStereochemistryProcess Chemistry and TechnologyFI catalystSubstituentDiastereomerDFTCatalysisphenoxyimineCatalysischemistry.chemical_compoundchemistryTransition metalPolymer chemistryDensity functional theoryPhysical and Theoretical Chemistryolefin polymerizationJournal of Molecular Catalysis A-Chemical
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Counter anion binding in the phenoxyimine, salan and metallocene olefin polymerization catalysts activated with perfluorophenylborate

2012

Abstract Ion pair separation is a process that may influence the activity of homogeneous catalysts of olefin polymerization. We have studied the energy of separation for selected titanium and zirconium metallocene and post-metallocene catalytic ion pairs by means of DFT, dispersion-corrected DFT and Paired Interacting Orbitals method (PIO). Unusually weak cation–anion interactions in the bis(phenoxyimine) systems were attributed to strong electron-donating properties of the phenoxyimine ligands. Energy decomposition analysis (EDA) revealed that almost 70% of the counter ion binding energy results from electrostatic interactions. The PIO method made it possible to analyze the nature of the c…

FI catalystBinding energyPopulationchemistry.chemical_elementPhotochemistryDFTBiochemistryCatalysisInorganic Chemistrychemistry.chemical_compoundPolymer chemistryMaterials ChemistryPhysical and Theoretical ChemistryAnion bindingeducationchemistry.chemical_classificationZirconiumeducation.field_of_studyOrganic Chemistryphenoxyiminechemistrypaired interacting orbitals (PIO)Counterionolefin polymerizationMetalloceneTitaniumJournal of Organometallic Chemistry
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A comparative study on the polymerization of 1-octene promoted by vanadium and titanium complexes supported by phenoxyimine and salen type ligands

2013

Polymerizations of 1-octene were carried out in the presence of vanadium and titanium complexes bearing salen-type or phenoxyimine ligands activated with various co-catalysts. Vanadium complexes turned out active only in conjunction with MAO, whereas the titanium ones were active in combination with Al(i-Bu)3/Ph3CB(C6F5)4. The activity of all catalysts was moderate or low and it was dependent on the ligand type: bis(phenoxyimine) complexes were more active than the salen ones. Both vanadium and titanium catalytic systems produced poly(1-octene)s possessing atactic structures with [mmmm] sequences in the range from 12 to 56 % at room temperature. A temperature decrease to 0.5 °C for the reac…

TitaniumMaterials sciencePolymers and PlasticsLigandOrganic Chemistrychemistry.chemical_elementVanadiumVanadiumChain transferZiegler-Natta polymerizationCatalysischemistry.chemical_compoundchemistryPolymerizationSalen ligandSalen ligandPhenoxyimine ligandPolymer chemistry1-octeneMaterials ChemistryOrganic chemistry1-OcteneTitaniumJournal of Polymer Research
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