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Hole-Induced Electron Transport through Core−Shell Quantum Dots: A Direct Measurement of the Electron−Hole Interaction

A Direct Measurement of the Electron-Hole Interaction

descriptionPublicationkeyboard_double_arrow_right Article 14 Apr 2010 Netherlands English Publisher:American Chemical Society (ACS)Journal:Nano Letters, volume 10, pages 1,931-1,935 (issn: 1530-6984, eissn: 1530-6992,

Authors: Daniel Vanmaekelbergh; Peter Liljeroth; Peter Liljeroth; Ingmar Swart; Zhixiang Sun;

doi: 10.1021/nl100949a

pmid: 20392107

Hole-Induced Electron Transport through Core−Shell Quantum Dots: A Direct Measurement of the Electron−Hole Interaction

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Abstract

Quantum dots (QDs) have promising optoelectronic properties. Colloidal QD heterostructures, systems in which two semiconductors are incorporated in a single colloid, may show novel and potentially useful transport phenomena. Here, we report on the physical mechanisms of charge transport through PbSe-CdSe core-shell QDs measured with cryogenic scanning tunneling spectroscopy. Compared to single-component QDs, an additional hole-induced electron tunneling channel is found. Electron tunneling with and without a hole occurs at different bias, allowing the determination of the electron-hole interaction energy (80 meV). This energy is sufficiently large to allow for a transport regime at room temperature in which electrons tunnel into the dot only if a hole is present, an ideal situation for controlled single-photon emission.

Country

Netherlands

Related Organizations

Utrecht University
Netherlands
Aalto University
Finland
Regensburg University of Applied Sciences
Germany
University Museum Utrecht
Netherlands
University of Regensburg
Germany

Keywords

electron-hole interaction, ambipolar electron transport, SCANNING TUNNELING SPECTROSCOPY, quantum dots, ta3112, Electron Transport, NANORODS, Electromagnetic Fields, scanning spectroscopy, Quantum Dots, HETEROSTRUCTURES, Scattering, Radiation, SEMICONDUCTOR NANOCRYSTALS, EXCHANGE, ta515, ta217, ta113, Core-shell, MONODISPERSE NANOCRYSTALS, ta114, ta3124, STATES, single-electron tunneling, Semiconductors, scanning tunneling, microscopy, scanning tunneling microscopy, scanning tunneling spectroscopy, PBSE, Core-shell quantum dots, EMISSION

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