0000000000194200

AUTHOR

Jean-luc Brédas

showing 4 related works from this author

Valence electronic structure of polystyrenes with different tacticities : how to go (or not to go) too far ? A joint theoretical and experimental app…

1990

Abstract Monochromadzed Al-K α XPS spectra from iso- and syndiotacdc polystyrenes are analyzed with the help of theoretical band structures and densities of states produced from a valence effective Hamiltonian (VEH) computation scheme. A discussion of the correlations found between the experimental and theoretical results points out to the potentialities but also to the limits of both methods.

RadiationValence (chemistry)ChemistryComputationElectronic structureCondensed Matter PhysicsAtomic and Molecular Physics and OpticsSpectral lineElectronic Optical and Magnetic Materialssymbols.namesakeX-ray photoelectron spectroscopysymbolsPhysical and Theoretical ChemistryAtomic physicsHamiltonian (quantum mechanics)SpectroscopyJournal of Electron Spectroscopy and Related Phenomena
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Electronic structure of polysilanes: influence of substitution and conformation

1993

Abstract The valence effective Hamiltonian (VEH) quantum-chemical approach is used to investigate the electronic properties of polysilane. The valence band structure calculated for this fully saturated polymer is analyzed in terms of orbital contributions and compared to that of the closely related carbon polymer, polyethylene. The effects of alkyl substitution and silicon backbone conformation are studied by elucidating the modifications that these structural changes induce on the electronic valence band structure of all-trans unsubstituted polysilane. The VEH results predict a decrease of the band gap upon alkyl substitution and on going from helical to all-trans conformations.

chemistry.chemical_classificationQuantitative Biology::BiomoleculesValence (chemistry)SiliconBand gapMechanical EngineeringMetals and Alloyschemistry.chemical_elementPolymerElectronic structurePolyethyleneCondensed Matter PhysicsElectronic Optical and Magnetic MaterialsCondensed Matter::Soft Condensed Matterchemistry.chemical_compoundsymbols.namesakeCrystallographychemistryMechanics of MaterialsComputational chemistryMaterials ChemistrysymbolsPolysilaneHamiltonian (quantum mechanics)Synthetic Metals
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Electronic structure of metal‐free phthalocyanine : A valence effective Hamiltonian theoretical study

1988

We present a valence effective Hamiltonian (VEH) nonempirical investigation of the electronic properties of metal‐free phthalocyanine. The valence one‐electron energy levels are related to those of the phthalocyanine components: benzene, pyrrole, and isoindole. From the electronic structure standpoint, phthalocyanine has to be viewed as formed by joining four benzene moieties to the central carbon–nitrogen ring rather than by combining four isoindole units through nitrogen bridges. Comparison of the VEH density‐of‐valence‐states curves with the experimental ultraviolet photoelectron spectroscopy (UPS) data is quantitatively excellent and allows for a complete interpretation of the experimen…

Valence (chemistry)PhthalocyaninesPhotoelectron SpectroscopyGeneral Physics and AstronomyElectronic structurePhthalocyanines ; Electronic Structure ; Valence ; Hamiltonian Function ; Photoelectron SpectroscopyPhotochemistryUNESCO::FÍSICA::Química físicachemistry.chemical_compoundsymbols.namesakeValenceX-ray photoelectron spectroscopychemistryElectronic StructurePhthalocyaninesymbolsHamiltonian FunctionPhysical chemistryPhysical and Theoretical ChemistryIsoindoleHamiltonian (quantum mechanics):FÍSICA::Química física [UNESCO]Ultraviolet photoelectron spectroscopyPyrrole
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Electronic structure of phthalocyanines : Theoretical investigation of the optical properties of phthalocyanine monomers, dimers, and crystals

1990

We present valence effective Hamiltonian (VEH) calculations on the optical absorptions of a series of phthalocyanine compounds: the metal‐free phthalocyanine molecule, a model system for the lithium phthalocyanine molecule, the metal‐free phthalocyanine dimer, and model systems for the lutetium diphthalocyanine and the lithium phthalocyanine crystal. For these compounds, it is found that the major factor influencing the evolution of the optical transitions is not the electronic structure of the metal but rather the geometric structure: phthalocyanine intraring geometry and, in the dimers and crystals, interring separation and staggering angle. The origin of the so‐called Soret or B absorpti…

Absorption SpectraAbsorption spectroscopyPhthalocyaninesGeneral Physics and AstronomyElectronic structurePhotochemistryCrystalchemistry.chemical_compoundHamiltonian FunctionMoleculePhysical and Theoretical ChemistryDimers:FÍSICA::Química física [UNESCO]Inorganic compoundchemistry.chemical_classificationValence (chemistry)MonomersMolecular CrystalsUNESCO::FÍSICA::Química físicaCrystallographyElectronic StructurechemistryAbsorption bandPhthalocyanineCondensed Matter::Strongly Correlated ElectronsElectronic Structure ; Molecular Crystals ; Dimers ; Monomers ; Absorption Spectra ; Hamiltonian Function ; Phthalocyanines
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