AI Article Synopsis
- Aliovalent doping of CdSe nanocrystals through cation exchange has led to unique optical and electronic properties, but a comprehensive understanding remains elusive due to challenges in characterizing these properties.
- Researchers used electrostatic force microscopy to measure the static charge on individual, cation-doped CdSe nanocrystals, revealing that while the charge was stable regardless of cation amount, there was a striking link between the average charge and photoluminescence (PL) intensity.
- The study suggests that the variations in PL intensity correspond to changes in the nanocrystal's radiative rate, influenced by alterations in the electronic states caused by the Coulombic interactions from the introduced ionized cations.
Article Abstract
Aliovalent doping of CdSe nanocrystals (NCs) via cation exchange processes has resulted in interesting and novel observations for the optical and electronic properties of the NCs. However, despite over a decade of study, these observations have largely gone unexplained, partially due to an inability to precisely characterize the physical properties of the doped NCs. Here, electrostatic force microscopy was used to determine the static charge on individual, cation-doped CdSe NCs in order to investigate their net charge as a function of added cations. While the NC charge was relatively insensitive to the relative amount of doped cation per NC, there was a remarkable and unexpected correlation between the average NC charge and PL intensity, for all dopant cations introduced. We conclude that the changes in PL intensity, as tracked also by changes in NC charge, are likely a consequence of changes in the NC radiative rate caused by symmetry breaking of the electronic states of the nominally spherical NC due to the Coulombic potential introduced by ionized cations.
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| http://dx.doi.org/10.1021/acs.nanolett.9b02284 | DOI Listing |
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