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DFT Calculations of InP Quantum Dots: Model Chemistries, Surface Passivation, and Open-Shell Singlet Ground States

Preston T. Snee

2021The Journal of Physical Chemistry C26 citationsDOI

Abstract

Density functional theory (DFT) calculations on large clusters of indium phosphide are presented. Several quantum dot-sized models, (NH3)64(InP)117, (COOH2)45(InP)117, (InCl3)29(InP)147, and (ZnCl2)29(InP)147, were passivated with organic or inorganic ligands; in some systems, both types were used. Initial results with the PBE1PBE functional proved puzzling as many clusters were initially found to have open-shell paramagnetic ground states, which is not sensible for nanoparticles of a direct band-gap semiconductor. In the case of QDs passivated with organic ligands, implementation of a robust geometry optimization procedure demonstrated that these findings were due to localization to metastable states and that the ground states are in fact diamagnetic singlets. However, the “nonstoichiometric” inorganic-passivated clusters (InCl3)29(InP)147 and (ZnCl2)29(InP)147 have ground nonet and septet states, respectively. Examination of the molecular orbitals revealed non-Aufbau state filling, suggesting the potential for open-shell singlet ground states, which is supported by calculations at the more robust M06-2x level of theory. Experimental evidence for paramagnetic or open-shell singlet ground states was not realized, which may be due to a mixture of inorganic and organic passivations.

Topics & Concepts

Open shellSinglet stateDensity functional theoryQuantum dotIndium phosphideGround stateParamagnetismChemistryPassivationDiamagnetismSurface statesMolecular physicsMaterials scienceComputational chemistryNanotechnologyExcited stateCondensed matter physicsAtomic physicsOptoelectronicsPhysicsGeometryGallium arsenideSurface (topology)Organic chemistryQuantum mechanicsLayer (electronics)MathematicsMagnetic fieldQuantum Dots Synthesis And PropertiesSemiconductor Quantum Structures and DevicesAdvanced Chemical Physics Studies
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