Conduction Band Fine Structure in Colloidal HgTe Quantum Dots

Margaret H. Hudson; Menglu Chen; Vladislav Kamysbayev; Eric M. Janke; Xinzheng Lan; Guy Allan; Christophe Delerue; Byeongdu Lee; Philippe Guyot-Sionnest; Dmitri V. Talapin

doi:10.1021/acsnano.8b04539

Conduction Band Fine Structure in Colloidal HgTe Quantum Dots

Margaret H. Hudson, Menglu Chen, Vladislav Kamysbayev, Eric M. Janke, Xinzheng Lan, Guy Allan, Christophe Delerue, Byeongdu Lee, Philippe Guyot-Sionnest, Dmitri V. Talapin^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

60 Citations (Scopus)

Abstract

HgTe colloidal quantum dots (QDs) are of interest because quantum confinement of semimetallic bulk HgTe allows one to synthetically control the bandgap throughout the infrared. Here, we synthesize highly monodisperse HgTe QDs and tune their doping both chemically and electrochemically. The monodispersity of the QDs was evaluated using small-angle X-ray scattering (SAXS) and suggests a diameter distribution of∼10% across multiple batches of different sizes. Electron-doped HgTe QDs display an intraband absorbance and bleaching of the first two excitonic features. We see splitting of the intraband peaks corresponding to electronic transitions from the occupied 1S_e state to a series of nondegenerate 1P_e states. Spectroelectrochemical studies reveal that the degree of splitting and relative intensity of the intraband features remain constant across doping levels up to two electrons per QD. Theoretical modeling suggests that the splitting of the 1P_e level arises from spin-orbit coupling and reduced QD symmetry. The fine structure of the intraband transitions is observed in the ensemble studies due to the size uniformity of the as-synthesized QDs and strong spin-orbit coupling inherent to HgTe.

Original language	English
Pages (from-to)	9397-9404
Number of pages	8
Journal	ACS Nano
Volume	12
Issue number	9
DOIs	https://doi.org/10.1021/acsnano.8b04539
Publication status	Published - 25 Sept 2018
Externally published	Yes

Keywords

colloidal quantum dots
doping
electronic structure
infrared
spectroelectrochemistry

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10.1021/acsnano.8b04539

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title = "Conduction Band Fine Structure in Colloidal HgTe Quantum Dots",

abstract = "HgTe colloidal quantum dots (QDs) are of interest because quantum confinement of semimetallic bulk HgTe allows one to synthetically control the bandgap throughout the infrared. Here, we synthesize highly monodisperse HgTe QDs and tune their doping both chemically and electrochemically. The monodispersity of the QDs was evaluated using small-angle X-ray scattering (SAXS) and suggests a diameter distribution of∼10% across multiple batches of different sizes. Electron-doped HgTe QDs display an intraband absorbance and bleaching of the first two excitonic features. We see splitting of the intraband peaks corresponding to electronic transitions from the occupied 1Se state to a series of nondegenerate 1Pe states. Spectroelectrochemical studies reveal that the degree of splitting and relative intensity of the intraband features remain constant across doping levels up to two electrons per QD. Theoretical modeling suggests that the splitting of the 1Pe level arises from spin-orbit coupling and reduced QD symmetry. The fine structure of the intraband transitions is observed in the ensemble studies due to the size uniformity of the as-synthesized QDs and strong spin-orbit coupling inherent to HgTe.",

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author = "Hudson, {Margaret H.} and Menglu Chen and Vladislav Kamysbayev and Janke, {Eric M.} and Xinzheng Lan and Guy Allan and Christophe Delerue and Byeongdu Lee and Philippe Guyot-Sionnest and Talapin, {Dmitri V.}",

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T1 - Conduction Band Fine Structure in Colloidal HgTe Quantum Dots

AU - Hudson, Margaret H.

AU - Chen, Menglu

AU - Kamysbayev, Vladislav

AU - Janke, Eric M.

AU - Lan, Xinzheng

AU - Allan, Guy

AU - Delerue, Christophe

AU - Lee, Byeongdu

AU - Guyot-Sionnest, Philippe

AU - Talapin, Dmitri V.

PY - 2018/9/25

Y1 - 2018/9/25

N2 - HgTe colloidal quantum dots (QDs) are of interest because quantum confinement of semimetallic bulk HgTe allows one to synthetically control the bandgap throughout the infrared. Here, we synthesize highly monodisperse HgTe QDs and tune their doping both chemically and electrochemically. The monodispersity of the QDs was evaluated using small-angle X-ray scattering (SAXS) and suggests a diameter distribution of∼10% across multiple batches of different sizes. Electron-doped HgTe QDs display an intraband absorbance and bleaching of the first two excitonic features. We see splitting of the intraband peaks corresponding to electronic transitions from the occupied 1Se state to a series of nondegenerate 1Pe states. Spectroelectrochemical studies reveal that the degree of splitting and relative intensity of the intraband features remain constant across doping levels up to two electrons per QD. Theoretical modeling suggests that the splitting of the 1Pe level arises from spin-orbit coupling and reduced QD symmetry. The fine structure of the intraband transitions is observed in the ensemble studies due to the size uniformity of the as-synthesized QDs and strong spin-orbit coupling inherent to HgTe.

AB - HgTe colloidal quantum dots (QDs) are of interest because quantum confinement of semimetallic bulk HgTe allows one to synthetically control the bandgap throughout the infrared. Here, we synthesize highly monodisperse HgTe QDs and tune their doping both chemically and electrochemically. The monodispersity of the QDs was evaluated using small-angle X-ray scattering (SAXS) and suggests a diameter distribution of∼10% across multiple batches of different sizes. Electron-doped HgTe QDs display an intraband absorbance and bleaching of the first two excitonic features. We see splitting of the intraband peaks corresponding to electronic transitions from the occupied 1Se state to a series of nondegenerate 1Pe states. Spectroelectrochemical studies reveal that the degree of splitting and relative intensity of the intraband features remain constant across doping levels up to two electrons per QD. Theoretical modeling suggests that the splitting of the 1Pe level arises from spin-orbit coupling and reduced QD symmetry. The fine structure of the intraband transitions is observed in the ensemble studies due to the size uniformity of the as-synthesized QDs and strong spin-orbit coupling inherent to HgTe.

KW - colloidal quantum dots

KW - doping

KW - electronic structure

KW - infrared

KW - spectroelectrochemistry

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JO - ACS Nano

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Conduction Band Fine Structure in Colloidal HgTe Quantum Dots

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