Control of Exciton Confinement
in Quantum Dot–Organic
Complexes through Energetic Alignment of Interfacial Orbitals

Frederick, Matthew
T.; Amin, Victor A.; Swenson, Nathaniel K.; Ho, Andrew Y.; Weiss, Emily A.

doi:10.1021/nl304098e.s001

Control of Exciton Confinement in Quantum Dot–Organic Complexes through Energetic Alignment of Interfacial Orbitals

journal contribution

posted on 2013-01-09, 00:00 authored by Matthew T. Frederick, Victor A. Amin, Nathaniel K. Swenson, Andrew Y. Ho, Emily A. Weiss

This paper describes a method to control the quantum confinement, and therefore the energy, of excitonic holes in CdSe QDs through adsorption of the hole-delocalizing ligand phenyldithiocarbamate, PTC, and para substitutions of the phenyl ring of this ligand with electron-donating or -withdrawing groups. These substitutions control hole delocalization in the QDs through the energetic alignment of the highest occupied orbitals of PTC with the highest density-of-states region of the CdSe valence band, to which PTC couples selectively.

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quantum confinement Exciton Confinement CdSe QDs Energetic Alignment Interfacial OrbitalsThis paper para substitutions excitonic holes phenyl ring substitutions control hole delocalization CdSe valence band ligand PTC couples

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CC BY-NC 4.0

Control of Exciton Confinement in Quantum Dot–Organic Complexes through Energetic Alignment of Interfacial Orbitals

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