Search results for "Time-dependent density functional theory"

showing 9 items of 59 documents

First-principles modelling for time-resolved ARPES under different pump-probe conditions

2021

First-principles methods for time-resolved angular resolved photoelectron spectroscopy play a pivotal role in providing interpretation and microscopic understanding of the complex experimental data and in exploring novel observables or observation conditions that may be achieved in future experiments. Here we describe an efficient, reliable and scalable first-principles method for tr-ARPES based on time-dependent density functional theory including propagation and surface effects usually discarded in the widely used many-body techniques based on computing the non-equilibrium spectral function and discuss its application to a variety of pump–probe conditions. We identify four conditions, dep…

Time-resolved angular resolved photoelectron spectroscopy (ARPES)Condensed Matter - Materials ScienceRadiationMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciences02 engineering and technologyTheoretical spectroscopy021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesAtomic and Molecular Physics and OpticsSettore FIS/03 - Fisica Della MateriaElectronic Optical and Magnetic MaterialsComputational methods for excitation in solids0103 physical sciencesTime-dependent density functional theoryPhysical and Theoretical Chemistry010306 general physics0210 nano-technologySpectroscopy
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Simulating pump-probe photo-electron and absorption spectroscopy on the attosecond time-scale with time-dependent density-functional theory

2013

Molecular absorption and photoelectron spectra can be efficiently predicted with real-time time-dependent density functional theory. We show herein how these techniques can be easily extended to study time-resolved pump-probe experiments, in which a system response (absorption or electron emission) to a probe pulse is measured in an excited state. This simulation tool helps with the interpretation of fast-evolving attosecond time-resolved spectroscopic experiments, in which electronic motion must be followed at its natural timescale. We show how the extra degrees of freedom (pump-pulse duration, intensity, frequency, and time delay), which are absent in a conventional steady-state experimen…

Time-resolved spectroscopyTime FactorsAbsorption spectroscopyAtomic Physics (physics.atom-ph)AttosecondAttosecond dynamicsFOS: Physical sciencesPump probesingle-molecule studies01 natural sciencestime-resolved spectroscopySettore FIS/03 - Fisica Della MateriaPhysics - Atomic PhysicsAb initio quantum chemistry methodsPhysics - Chemical Physics0103 physical sciencesPhysics - Atomic and Molecular ClustersLaser spectroscopyPhysical and Theoretical Chemistry010306 general physicsSpectroscopyPhysicsChemical Physics (physics.chem-ph)010304 chemical physicsEuropean researchab initio calculationsPhotoelectron SpectroscopySingle-molecule studiesattosecond dynamicsTime-dependent density functional theoryAtomic and Molecular Physics and OpticsPhysics - Plasma PhysicsPlasma Physics (physics.plasm-ph)X-Ray Absorption Spectroscopylaser spectroscopyQuantum TheoryAtomic physicsTime-resolved spectroscopyAtomic and Molecular Clusters (physics.atm-clus)
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Iron’s Wake: The Performance of Quantum Mechanical-Derived Versus General-Purpose Force Fields Tested on a Luminescent Iron Complex

2020

Recently synthetized iron complexes have achieved long-lived excited states and stabilities which are comparable, or even superior, to their ruthenium analogues, thus representing an eco-friendly and cheaper alternative to those materials based on rare metals. Most of computational tools which could help unravel the origin of this large efficiency rely on ab-initio methods which are not able, however, to capture the nanosecond time scale underlying these photophysical processes and the influence of their realistic environment. Therefore, it exists an urgent need of developing new low-cost, but still accurate enough, computational methodologies capable to deal with the steady-state and trans…

Work (thermodynamics)AcetonitrilesLuminescenceIronPharmaceutical ScienceMolecular Dynamics Simulation010402 general chemistry01 natural sciencesArticleAnalytical Chemistrylcsh:QD241-441Molecular dynamicschemical environmentlcsh:Organic chemistry0103 physical sciencesDrug Discoverytime-dependent density functional theory.Statistical physicsPhysical and Theoretical ChemistryQuantumComputingMilieux_MISCELLANEOUSPhysics010304 chemical physicsSpectrum AnalysisScale (chemistry)Organic ChemistryTime-dependent density functional theoryNanosecond0104 chemical sciences[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistrytime-dependent density functional theoryiron complexChemistry (miscellaneous)Excited stateSolventsQuantum TheoryMolecular MedicineLuminescenceIron Compoundsforce field molecular dynamicsMolecules
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Modelling the effect of nuclear motion on the attosecond time-resolved photoelectron spectra of ethylene

2014

arXiv:1403.5408

attosecond pump probeAttosecondFOS: Physical sciencesElectronmedicine.disease_cause01 natural sciencesSpectral lineSettore FIS/03 - Fisica Della Materianuclear motionTDDFTPhysics - Chemical Physics0103 physical sciencesmedicinePhysics::Atomic and Molecular ClustersMoleculePhysics - Atomic and Molecular ClustersPhysics::Chemical Physics010306 general physicsPhysicsChemical Physics (physics.chem-ph)010304 chemical physicsTRPESTime-dependent density functional theoryCondensed Matter PhysicsAtomic and Molecular Physics and Optics3. Good healthExtreme ultravioletFemtosecondAtomic physicsAtomic and Molecular Clusters (physics.atm-clus)Ultraviolet
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Merging Features from Green's Functions and Time Dependent Density Functional Theory: A Route to the Description of Correlated Materials out of Equil…

2016

We propose a description of nonequilibrium systems via a simple protocol that combines exchange-correlation potentials from density functional theory with self-energies of many-body perturbation theory. The approach, aimed to avoid double counting of interactions, is tested against exact results in Hubbard-type systems, with respect to interaction strength, perturbation speed and inhomogeneity, and system dimensionality and size. In many regimes, we find significant improvement over adiabatic time dependent density functional theory or second Born nonequilibrium Green's function approximations. We briefly discuss the reasons for the residual discrepancies, and directions for future work.

out of equilibriumexchange-correlation potentialmany body perturbation theoryGeneral Physics and AstronomyPerturbation (astronomy)Non-equilibrium thermodynamicsFOS: Physical sciences02 engineering and technologyResidual01 natural sciencesnon-equilibrium Green's functionCondensed Matter - Strongly Correlated Electronstime dependent density functional theory0103 physical sciencesMesoscale and Nanoscale Physics (cond-mat.mes-hall)Statistical physicsnonequilibrium system010306 general physicsAdiabatic processcorrelated materialsPhysicsCondensed Matter - Materials Scienceta114Strongly Correlated Electrons (cond-mat.str-el)Condensed Matter - Mesoscale and Nanoscale PhysicsMaterials Science (cond-mat.mtrl-sci)Time-dependent density functional theory021001 nanoscience & nanotechnologyinteraction strengthperturbation techniquesFunction approximationDensity functional theory0210 nano-technologyCurse of dimensionality
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Kohn-Sham Decomposition in Real-Time Time-Dependent Density-Functional Theory An Efficient Tool for Analyzing Plasmonic Excitations

2017

The real-time-propagation formulation of time-dependent density-functional theory (RT-TDDFT) is an efficient method for modeling the optical response of molecules and nanoparticles. Compared to the widely adopted linear-response TDDFT approaches based on, e.g., the Casida equations, RT-TDDFT appears, however, lacking efficient analysis methods. This applies in particular to a decomposition of the response in the basis of the underlying single-electron states. In this work, we overcome this limitation by developing an analysis method for obtaining the Kohn-Sham electron-hole decomposition in RT-TDDFT. We demonstrate the equivalence between the developed method and the Casida approach by a be…

plasmonic excitationsTheoretical computer scienceKohn-Sham decompositionComputer scienceta221Kohn–Sham equationsFOS: Physical sciencesPhysics::Optics02 engineering and technology01 natural sciencesPhysics - Chemical Physics0103 physical sciencesMesoscale and Nanoscale Physics (cond-mat.mes-hall)Decomposition (computer science)Physics::Atomic and Molecular ClustersStatistical physicsPhysical and Theoretical ChemistryPhysics::Chemical Physics010306 general physicsta116PlasmonEigenvalues and eigenvectorsChemical Physics (physics.chem-ph)Condensed Matter - Materials ScienceCondensed Matter - Mesoscale and Nanoscale Physicsta114tiheysfunktionaaliteoriaMaterials Science (cond-mat.mtrl-sci)Time-dependent density functional theory16. Peace & justice021001 nanoscience & nanotechnologyComputer Science ApplicationsplasmonitBenzene derivativesnanohiukkaset0210 nano-technologyJOURNAL OF CHEMICAL THEORY AND COMPUTATION
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Localized surface plasmon resonance in silver nanoparticles: Atomistic first-principles time-dependent density-functional theory calculations

2015

We observe using ab initio methods that localized surface plasmon resonances in icosahedral silver nanoparticles enter the asymptotic region already between diameters of 1 and 2 nm, converging close to the classical quasistatic limit around 3.4 eV. We base the observation on time-dependent density-functional theory simulations of the icosahedral silver clusters Ag$_{55}$ (1.06 nm), Ag$_{147}$ (1.60 nm), Ag$_{309}$ (2.14 nm), and Ag$_{561}$ (2.68 nm). The simulation method combines the adiabatic GLLB-SC exchange-correlation functional with real time propagation in an atomic orbital basis set using the projector-augmented wave method. The method has been implemented for the electron structure…

silver nanoparticlesMaterials scienceta221Ab initioFOS: Physical sciencesMetal nanoparticlesMolecular physicsAtomic orbitalTime-dependent density functional theorySurface plasmon resonanceta116ta218Basis setPlasmonCondensed Matter - Materials Scienceta214ta114Condensed matter physicsMaterials Science (cond-mat.mtrl-sci)Time-dependent density functional theoryCondensed Matter PhysicsNanoshellElectronic Optical and Magnetic MaterialsPlasmonicssurface plasmon resonanceLocalized surface plasmonPhysical Review B
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TDDFT Analysis of Optical Properties of Thiol Monolayer-Protected Gold and Intermetallic Silver–Gold Au144(SR)60 and Au84Ag60(SR)60 Clusters

2014

The optical absorption spectra of atomistic model structures for experimentally isolated all-gold Au144(SR)60 and intermetallic Au84Ag60(SR)60 clusters are systematically analyzed from linear-response time-dependent density functional theory (LR-TDDFT) and time-dependent density functional perturbation theory (TD-DFPT) calculations. The computed spectra, utilizing the atomistic model for Au144(SR)60 published by us in 2009, reproduce closely the experimental observations for corresponding isolated compounds, reported previously by Kumara and Dass in 2011. A collective dipole oscillation within the metal cores of the all-gold and intermetallic clusters is formed as response to light in the v…

ta114ChemistryIntermetallicTime-dependent density functional theoryMolecular physicsSpectral lineSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsMetalDipoleGeneral Energyvisual_artMonolayervisual_art.visual_art_mediumDensity functional theoryPhysical and Theoretical ChemistrySurface plasmon resonanceAtomic physicsta116The Journal of Physical Chemistry C
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Optical Properties of Monolayer-Protected Aluminum Clusters: Time-Dependent Density Functional Theory Study

2015

We examine the electronic and optical properties of experimentally known monolayer-protected aluminum clusters Al4(C5H5)4, Al50(C5Me5)12, and Al69(N(SiMe3)2)183– using time-dependent density functional theory. By comparing Al4(C5H5)4 and the theoretical Al4(N(SiMe3)2)4 cluster, we observe significant changes in the optical absorption spectra caused by different hybridization between metal core and ligands. Using these initial observations, we explain the calculated spectra of Al50(C5Me5)12 and Al69(N(SiMe3)2)183–. Al50(C5Me5)12 shows a structured spectrum with clear regions of low-intensity core-to-core transitions followed by high-intensity ligand-to-core transitions due to its high symmet…

ta114Chemistrychemistry.chemical_elementTime-dependent density functional theorySpectral lineSymmetry (physics)3. Good healthSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialsaluminum clustersMetalCrystallographytime-dependent density functional theoryGeneral EnergyAluminiumvisual_artMonolayervisual_art.visual_art_mediumCluster (physics)Density functional theoryPhysical and Theoretical Chemistryta116Journal of Physical Chemistry C
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