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Room temperature synthesis of HgTe quantum dots in an aprotic solvent realizing high photoluminescence quantum yields in the infrared

Room temperature synthesis of HgTe quantum dots in an aprotic solvent realizing high photoluminescence quantum yields in the infrared
Room temperature synthesis of HgTe quantum dots in an aprotic solvent realizing high photoluminescence quantum yields in the infrared
A computer controlled, automated synthesis method has been used to grow HgTe quantum dots (QDs) entirely at room temperature, using an aprotic solvent, dimethyl sulfoxide. The growth is carried out with small iterative additions of the Te precursor, which allows frequent sampling of the products to assess the growth trajectory in terms of the relationship between the QD concentration and QD diameters as the reaction proceeds. As such, this approach is a useful tool to develop a detailed understanding of the growth process and to work toward optimizing the reaction conditions in terms of the quality of the resulting QDs. HgTe QDs with emission spectra ranging up to 3000 nm and with photoluminescence quantum yields of up to 17% at 2070 nm have been produced by this method. Although coupling of the exciton to ligand vibrations is inevitable in this energy range, attention to the growth conditions and QD quality can influence the detailed coupling mechanisms, with fewer carrier traps reducing the extent of polaron mediated coupling. The influence of reaction conditions such as ligand-to-cation ratios and rate of Te precursor addition upon the onset of QD aggregation has been also examined. The method is readily up-scalable and has been employed to produce HgTe QD materials for infrared photodetectors.
0897-4756
7859–7867
Abdelazim, Nema
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Zhu, Qiang
d1e9b689-8ce1-4adb-816a-7af76695d7e5
Xiong, Yuan
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Zhu, Ye
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Chen, Mengyu
aba99ba1-d648-46ab-9074-dcdd1cc21e5a
Zhao, Ni
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Kershaw, Stephen V.
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Rogach, Andrey L.
d0a997c0-90ab-4d49-a788-6c09e3e0cb46
Abdelazim, Nema
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Zhu, Qiang
d1e9b689-8ce1-4adb-816a-7af76695d7e5
Xiong, Yuan
b6f5e75d-2636-40d3-9a36-4d19d9242a4c
Zhu, Ye
b20d18f4-b0e0-4202-b5fc-dcc26840489c
Chen, Mengyu
aba99ba1-d648-46ab-9074-dcdd1cc21e5a
Zhao, Ni
78ce4eb4-ebd6-448c-aff5-69bef68dd5c1
Kershaw, Stephen V.
92350526-451a-4269-999a-afc0f11139e9
Rogach, Andrey L.
d0a997c0-90ab-4d49-a788-6c09e3e0cb46

Abdelazim, Nema, Zhu, Qiang, Xiong, Yuan, Zhu, Ye, Chen, Mengyu, Zhao, Ni, Kershaw, Stephen V. and Rogach, Andrey L. (2017) Room temperature synthesis of HgTe quantum dots in an aprotic solvent realizing high photoluminescence quantum yields in the infrared. Chemistry of Materials, 7859–7867. (doi:10.1021/acs.chemmater.7b02637).

Record type: Article

Abstract

A computer controlled, automated synthesis method has been used to grow HgTe quantum dots (QDs) entirely at room temperature, using an aprotic solvent, dimethyl sulfoxide. The growth is carried out with small iterative additions of the Te precursor, which allows frequent sampling of the products to assess the growth trajectory in terms of the relationship between the QD concentration and QD diameters as the reaction proceeds. As such, this approach is a useful tool to develop a detailed understanding of the growth process and to work toward optimizing the reaction conditions in terms of the quality of the resulting QDs. HgTe QDs with emission spectra ranging up to 3000 nm and with photoluminescence quantum yields of up to 17% at 2070 nm have been produced by this method. Although coupling of the exciton to ligand vibrations is inevitable in this energy range, attention to the growth conditions and QD quality can influence the detailed coupling mechanisms, with fewer carrier traps reducing the extent of polaron mediated coupling. The influence of reaction conditions such as ligand-to-cation ratios and rate of Te precursor addition upon the onset of QD aggregation has been also examined. The method is readily up-scalable and has been employed to produce HgTe QD materials for infrared photodetectors.

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Published date: 30 August 2017

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Local EPrints ID: 452485
URI: http://eprints.soton.ac.uk/id/eprint/452485
ISSN: 0897-4756
PURE UUID: 435fe5d6-ebd5-4860-9838-8d132a06a286

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Date deposited: 11 Dec 2021 11:18
Last modified: 16 Mar 2024 14:22

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Contributors

Author: Nema Abdelazim
Author: Qiang Zhu
Author: Yuan Xiong
Author: Ye Zhu
Author: Mengyu Chen
Author: Ni Zhao
Author: Stephen V. Kershaw
Author: Andrey L. Rogach

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