Single molecule quantum-confined Stark effect measurements of semiconductor nanoparticles at room temperature

Kyoungwon Park; Zvicka Deutsch; J. Jack Li; Dan Oron; Shimon Weiss

doi:10.1021/nn303719m

Single molecule quantum-confined Stark effect measurements of semiconductor nanoparticles at room temperature

Kyoungwon Park, Zvicka Deutsch, J. Jack Li, Dan Oron, Shimon Weiss

Department of Physics of Complex Systems

Weizmann Institute of Science

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

Abstract

We measured the quantum-confined Stark effect (QCSE) of several types of fluorescent colloidal semiconductor quantum dots and nanorods at the single molecule level at room temperature. These measurements demonstrate the possible utility of these nanoparticles for local electric field (voltage) sensing on the nanoscale. Here we show that charge separation across one (or more) heterostructure interface(s) with type-II band alignment (and the associated induced dipole) is crucial for an enhanced QCSE. To further gain insight into the experimental results, we numerically solved the Schrödinger and Poisson equations under self-consistent field approximation, including dielectric inhomogeneities. Both calculations and experiments suggest that the degree of initial charge separation (and the associated exciton binding energy) determines the magnitude of the QCSE in these structures.

Original language	American English
Pages (from-to)	10013-10023
Number of pages	11
Journal	ACS Nano
Volume	6
Issue number	11
DOIs	https://doi.org/10.1021/nn303719m
State	Published - 27 Nov 2012

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

nanorod
quantum dot
quantum-confined Stark effect
type-I band alignment
type-II band alignment
voltage sensing
wave function engineering

All Science Journal Classification (ASJC) codes

General Materials Science
General Engineering
General Physics and Astronomy

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10.1021/nn303719m

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@article{7bd815424ee04890866217b6d31b8303,

title = "Single molecule quantum-confined Stark effect measurements of semiconductor nanoparticles at room temperature",

abstract = "We measured the quantum-confined Stark effect (QCSE) of several types of fluorescent colloidal semiconductor quantum dots and nanorods at the single molecule level at room temperature. These measurements demonstrate the possible utility of these nanoparticles for local electric field (voltage) sensing on the nanoscale. Here we show that charge separation across one (or more) heterostructure interface(s) with type-II band alignment (and the associated induced dipole) is crucial for an enhanced QCSE. To further gain insight into the experimental results, we numerically solved the Schr{\"o}dinger and Poisson equations under self-consistent field approximation, including dielectric inhomogeneities. Both calculations and experiments suggest that the degree of initial charge separation (and the associated exciton binding energy) determines the magnitude of the QCSE in these structures.",

keywords = "nanorod, quantum dot, quantum-confined Stark effect, type-I band alignment, type-II band alignment, voltage sensing, wave function engineering",

author = "Kyoungwon Park and Zvicka Deutsch and Li, {J. Jack} and Dan Oron and Shimon Weiss",

note = "NIH [5R01EB000312, 1R01GM086197]; BSF [2010382]; ERC [258221 SINSLIM]We thank Dr. Y. Ebenstein for help with the optical setup, Dr. X. Michalet for help with measurement automation, and K. Sato and A. Pan for useful discussions of quantum calculation. This work was supported by NIH Grant Nos. 5R01EB000312 and 1R01GM086197 (to SW.), BSF Grant No. 2010382 (to SW. and D.O.), and ERC (to DO., Starting Investigator Grant No. 258221 SINSLIM).",

year = "2012",

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doi = "10.1021/nn303719m",

language = "American English",

volume = "6",

pages = "10013--10023",

journal = "ACS Nano",

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T1 - Single molecule quantum-confined Stark effect measurements of semiconductor nanoparticles at room temperature

AU - Park, Kyoungwon

AU - Deutsch, Zvicka

AU - Li, J. Jack

AU - Oron, Dan

AU - Weiss, Shimon

N1 - NIH [5R01EB000312, 1R01GM086197]; BSF [2010382]; ERC [258221 SINSLIM]We thank Dr. Y. Ebenstein for help with the optical setup, Dr. X. Michalet for help with measurement automation, and K. Sato and A. Pan for useful discussions of quantum calculation. This work was supported by NIH Grant Nos. 5R01EB000312 and 1R01GM086197 (to SW.), BSF Grant No. 2010382 (to SW. and D.O.), and ERC (to DO., Starting Investigator Grant No. 258221 SINSLIM).

PY - 2012/11/27

Y1 - 2012/11/27

N2 - We measured the quantum-confined Stark effect (QCSE) of several types of fluorescent colloidal semiconductor quantum dots and nanorods at the single molecule level at room temperature. These measurements demonstrate the possible utility of these nanoparticles for local electric field (voltage) sensing on the nanoscale. Here we show that charge separation across one (or more) heterostructure interface(s) with type-II band alignment (and the associated induced dipole) is crucial for an enhanced QCSE. To further gain insight into the experimental results, we numerically solved the Schrödinger and Poisson equations under self-consistent field approximation, including dielectric inhomogeneities. Both calculations and experiments suggest that the degree of initial charge separation (and the associated exciton binding energy) determines the magnitude of the QCSE in these structures.

AB - We measured the quantum-confined Stark effect (QCSE) of several types of fluorescent colloidal semiconductor quantum dots and nanorods at the single molecule level at room temperature. These measurements demonstrate the possible utility of these nanoparticles for local electric field (voltage) sensing on the nanoscale. Here we show that charge separation across one (or more) heterostructure interface(s) with type-II band alignment (and the associated induced dipole) is crucial for an enhanced QCSE. To further gain insight into the experimental results, we numerically solved the Schrödinger and Poisson equations under self-consistent field approximation, including dielectric inhomogeneities. Both calculations and experiments suggest that the degree of initial charge separation (and the associated exciton binding energy) determines the magnitude of the QCSE in these structures.

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KW - quantum dot

KW - quantum-confined Stark effect

KW - type-I band alignment

KW - type-II band alignment

KW - voltage sensing

KW - wave function engineering

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JO - ACS Nano

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ER -

Single molecule quantum-confined Stark effect measurements of semiconductor nanoparticles at room temperature

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Keywords

All Science Journal Classification (ASJC) codes

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