2023
Combining three sources of optical anisotropy in a tunable open-access microcavity: From theory to experiment
Li Y, Luo X, Guo Y, Ren J, Long T, Wang B, Cai Y, Guo C, Qin Y, Fu H, Zhang Y, Yun F, Liao Q, Li F. Combining three sources of optical anisotropy in a tunable open-access microcavity: From theory to experiment. Journal Of Applied Physics 2023, 134: 223106. DOI: 10.1063/5.0173709.Peer-Reviewed Original ResearchOpen‐access microcavityPhotonic spin-orbit couplingTE-TM splittingSpin-orbit couplingFine energy splittingOptical property measurementsEmergent anisotropyMicrocavity photonsImportant physical mechanismsDegenerate perturbation theoryPhotonic devicesExciton-polaritonsPhotonic potentialPolarization controlSO couplingOptical anisotropySpin vorticesActive mediumEnergy splittingClear observationPhysical mechanismsPerturbation theoryMicrocavitiesIsotropic situationEigenstates
2015
Coupled-Cluster Studies of Extensive Green Fluorescent Protein Models Using the Reduced Virtual Space Approach
Send R, Suomivuori C, Kaila V, Sundholm D. Coupled-Cluster Studies of Extensive Green Fluorescent Protein Models Using the Reduced Virtual Space Approach. The Journal Of Physical Chemistry B 2015, 119: 2933-2945. PMID: 25613980, DOI: 10.1021/jp5120898.Peer-Reviewed Original ResearchConceptsReduced virtual spaceProtonation stateExcited statesCoupled-clusterCalculation of excitation energiesMethods of theoretical chemistryExcitation energyCC2 excitation energiesCoupled-cluster studyCoupled-cluster singlesLowest excited stateQuantum mechanical calculationsExperimental absorption spectraCalculated energy splittingsStudy of excited statesQM regionVirtual orbitalsPhotoexcitation propertiesMechanical calculationsAbsorption spectraTheoretical chemistryEnergy splittingProtein modelsPredicted optical propertiesBiomolecular systems
2014
Electronic Structure and Chemical Nature of Oxygen Dopant States in Carbon Nanotubes
Ma X, Adamska L, Yamaguchi H, Yalcin SE, Tretiak S, Doorn SK, Htoon H. Electronic Structure and Chemical Nature of Oxygen Dopant States in Carbon Nanotubes. ACS Nano 2014, 8: 10782-10789. PMID: 25265272, DOI: 10.1021/nn504553y.Peer-Reviewed Original ResearchSingle-walled carbon nanotubesCarbon nanotubesOxygen-doped single-walled carbon nanotubesEmission peakElectronic structure simulationsLocal dielectric environmentChemical adductsDeep trap statesChemical natureAsymmetric emission peaksElectronic structureE11 excitonNanotubesOxygen dopingSingle nanotubePhotoluminescence studiesDopant statesDielectric environmentTemperature photoluminescence studiesAdductsTrap statesStructure simulationsBright exciton peakSpectral featuresEnergy splitting
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