The Effect of Ligands and Solvents on Nonradiative Transitions in Semiconductor Quantum Dots (A Review)

The Effect of Ligands and Solvents on Nonradiative Transitions in Semiconductor Quantum Dots (A Review)

Data on quantum yields and photoluminescence decay times of quantum dots have been collected. Photoprocesses that occur in quantum dots are compared with photoprocesses occurring in complex organic molecules in the condensed phase. The review consists of the introduction, three parts, and conclusion...

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Bibliographic Details
Published in:Optics and spectroscopy Vol. 125; no. 2; pp. 256 - 274
Main Author: Ermolaev, V. L.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-08-2018
Springer Nature B.V
Subjects:
CARBON
Decay
ELECTRONIC STRUCTURE
Electrons
Lasers
Mesostructures
Metamaterials
MOLECULES
NANOSCIENCE AND NANOTECHNOLOGY
Optical Devices
Optics
Optics of Low-Dimensional Structures
Organic chemistry
PHOTOLUMINESCENCE
Photonics
Physics
Physics and Astronomy
QUANTUM DOTS
RELAXATION
RESONANCE
SEMICONDUCTOR MATERIALS
Semiconductors
SILICON
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Summary:Data on quantum yields and photoluminescence decay times of quantum dots have been collected. Photoprocesses that occur in quantum dots are compared with photoprocesses occurring in complex organic molecules in the condensed phase. The review consists of the introduction, three parts, and conclusions. The first two parts are devoted to quantum dots that are formed by indirect-gap semiconductors. The first part is devoted to data on the photoluminescence quantum yields and decay times of carbon quantum dots, and Table 1 presents selected values and short comments to these data. Table 2 of the same part presents data on fast relaxation processes in the same objects. In the second part, Tables 3 and 4, as well as the following text, contain similar information about silicon quantum dots. Data on photoprocesses in quantum dots formed by direct-gap semiconductors are collected in the third part. Data on the photoluminescence yields, decay times, and relaxation processes are listed in Tables 5 and 6. Particular attention in the present review is given to the effect that a change in the frequency of vibrations in the environment of a quantum dot has on the photoluminescence yields and the rate of relaxation processes between electronic levels in bands, which indicates that the inductive resonance mechanism of nonradiative transitions is applicable to these systems.
ISSN:0030-400X
1562-6911
DOI:10.1134/S0030400X18080052