A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics

Younghoon Kim; Fanglin Che; Jea Woong Jo; Jongmin Choi; F. Pelayo García de Arquer; Oleksandr Voznyy; Bin Sun; Junghwan Kim; Min Jae Choi; Rafael Quintero-Bermudez; Fengjia Fan; Chih Shan Tan; Eva Bladt; Grant Walters; Andrew H. Proppe; Chengqin Zou; Haifeng Yuan; Sara Bals; Johan Hofkens; Maarten B.J. Roeffaers; Sjoerd Hoogland; Edward H. Sargent

doi:10.1002/adma.201805580

A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics

Younghoon Kim
, Fanglin Che
, Jea Woong Jo
, Jongmin Choi
, F. Pelayo García de Arquer
, Oleksandr Voznyy
, Bin Sun
, Junghwan Kim
, Min Jae Choi
, Rafael Quintero-Bermudez
, Fengjia Fan
, Chih Shan Tan
, Eva Bladt
, Grant Walters
, Andrew H. Proppe
, Chengqin Zou
, Haifeng Yuan
, Sara Bals
, Johan Hofkens
, Maarten B.J. Roeffaers

Sjoerd Hoogland, Edward H. Sargent

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

117 Scopus citations

Abstract

Colloidal nanocrystals combine size- and facet-dependent properties with solution processing. They offer thus a compelling suite of materials for technological applications. Their size- and facet-tunable features are studied in synthesis; however, to exploit their features in optoelectronic devices, it will be essential to translate control over size and facets from the colloid all the way to the film. Larger-diameter colloidal quantum dots (CQDs) offer the attractive possibility of harvesting infrared (IR) solar energy beyond absorption of silicon photovoltaics. These CQDs exhibit facets (nonpolar (100)) undisplayed in small-diameter CQDs; and the materials chemistry of smaller nanocrystals fails consequently to translate to materials for the short-wavelength IR regime. A new colloidal management strategy targeting the passivation of both (100) and (111) facets is demonstrated using distinct choices of cations and anions. The approach leads to narrow-bandgap CQDs with impressive colloidal stability and photoluminescence quantum yield. Photophysical studies confirm a reduction both in Stokes shift (≈47 meV) and Urbach tail (≈29 meV). This approach provides a ≈50% increase in the power conversion efficiency of IR photovoltaics compared to controls, and a ≈70% external quantum efficiency at their excitonic peak.

Original language	English
Article number	1805580
Journal	Advanced Materials
Volume	31
Issue number	17
DOIs	https://doi.org/10.1002/adma.201805580
State	Published - 25 Apr 2019

Keywords

colloidal quantum dots
facet-specific passivation
infrared solar cells
narrow bandgap
sodium acetate

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10.1002/adma.201805580

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Kim, Y., Che, F., Jo, J. W., Choi, J., García de Arquer, F. P., Voznyy, O., Sun, B., Kim, J., Choi, M. J., Quintero-Bermudez, R., Fan, F., Tan, C. S., Bladt, E., Walters, G., Proppe, A. H., Zou, C., Yuan, H., Bals, S., Hofkens, J., ... Sargent, E. H. (2019). A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics. Advanced Materials, 31(17), Article 1805580. https://doi.org/10.1002/adma.201805580

@article{aa559f6f04be4f3fadfe0f64d5084677,

title = "A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics",

abstract = "Colloidal nanocrystals combine size- and facet-dependent properties with solution processing. They offer thus a compelling suite of materials for technological applications. Their size- and facet-tunable features are studied in synthesis; however, to exploit their features in optoelectronic devices, it will be essential to translate control over size and facets from the colloid all the way to the film. Larger-diameter colloidal quantum dots (CQDs) offer the attractive possibility of harvesting infrared (IR) solar energy beyond absorption of silicon photovoltaics. These CQDs exhibit facets (nonpolar (100)) undisplayed in small-diameter CQDs; and the materials chemistry of smaller nanocrystals fails consequently to translate to materials for the short-wavelength IR regime. A new colloidal management strategy targeting the passivation of both (100) and (111) facets is demonstrated using distinct choices of cations and anions. The approach leads to narrow-bandgap CQDs with impressive colloidal stability and photoluminescence quantum yield. Photophysical studies confirm a reduction both in Stokes shift (≈47 meV) and Urbach tail (≈29 meV). This approach provides a ≈50\% increase in the power conversion efficiency of IR photovoltaics compared to controls, and a ≈70\% external quantum efficiency at their excitonic peak.",

keywords = "colloidal quantum dots, facet-specific passivation, infrared solar cells, narrow bandgap, sodium acetate",

author = "Younghoon Kim and Fanglin Che and Jo, \{Jea Woong\} and Jongmin Choi and \{Garc{\'i}a de Arquer\}, \{F. Pelayo\} and Oleksandr Voznyy and Bin Sun and Junghwan Kim and Choi, \{Min Jae\} and Rafael Quintero-Bermudez and Fengjia Fan and Tan, \{Chih Shan\} and Eva Bladt and Grant Walters and Proppe, \{Andrew H.\} and Chengqin Zou and Haifeng Yuan and Sara Bals and Johan Hofkens and Roeffaers, \{Maarten B.J.\} and Sjoerd Hoogland and Sargent, \{Edward H.\}",

note = "Publisher Copyright: {\textcopyright} 2019 WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2019",

month = apr,

day = "25",

doi = "10.1002/adma.201805580",

language = "English",

volume = "31",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley-Blackwell",

number = "17",

}

Kim, Y, Che, F, Jo, JW, Choi, J, García de Arquer, FP, Voznyy, O, Sun, B, Kim, J, Choi, MJ, Quintero-Bermudez, R, Fan, F, Tan, CS, Bladt, E, Walters, G, Proppe, AH, Zou, C, Yuan, H, Bals, S, Hofkens, J, Roeffaers, MBJ, Hoogland, S & Sargent, EH 2019, 'A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics', Advanced Materials, vol. 31, no. 17, 1805580. https://doi.org/10.1002/adma.201805580

TY - JOUR

T1 - A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics

AU - Kim, Younghoon

AU - Che, Fanglin

AU - Jo, Jea Woong

AU - Choi, Jongmin

AU - García de Arquer, F. Pelayo

AU - Voznyy, Oleksandr

AU - Sun, Bin

AU - Kim, Junghwan

AU - Choi, Min Jae

AU - Quintero-Bermudez, Rafael

AU - Fan, Fengjia

AU - Tan, Chih Shan

AU - Bladt, Eva

AU - Walters, Grant

AU - Proppe, Andrew H.

AU - Zou, Chengqin

AU - Yuan, Haifeng

AU - Bals, Sara

AU - Hofkens, Johan

AU - Roeffaers, Maarten B.J.

AU - Hoogland, Sjoerd

AU - Sargent, Edward H.

PY - 2019/4/25

Y1 - 2019/4/25

N2 - Colloidal nanocrystals combine size- and facet-dependent properties with solution processing. They offer thus a compelling suite of materials for technological applications. Their size- and facet-tunable features are studied in synthesis; however, to exploit their features in optoelectronic devices, it will be essential to translate control over size and facets from the colloid all the way to the film. Larger-diameter colloidal quantum dots (CQDs) offer the attractive possibility of harvesting infrared (IR) solar energy beyond absorption of silicon photovoltaics. These CQDs exhibit facets (nonpolar (100)) undisplayed in small-diameter CQDs; and the materials chemistry of smaller nanocrystals fails consequently to translate to materials for the short-wavelength IR regime. A new colloidal management strategy targeting the passivation of both (100) and (111) facets is demonstrated using distinct choices of cations and anions. The approach leads to narrow-bandgap CQDs with impressive colloidal stability and photoluminescence quantum yield. Photophysical studies confirm a reduction both in Stokes shift (≈47 meV) and Urbach tail (≈29 meV). This approach provides a ≈50% increase in the power conversion efficiency of IR photovoltaics compared to controls, and a ≈70% external quantum efficiency at their excitonic peak.

AB - Colloidal nanocrystals combine size- and facet-dependent properties with solution processing. They offer thus a compelling suite of materials for technological applications. Their size- and facet-tunable features are studied in synthesis; however, to exploit their features in optoelectronic devices, it will be essential to translate control over size and facets from the colloid all the way to the film. Larger-diameter colloidal quantum dots (CQDs) offer the attractive possibility of harvesting infrared (IR) solar energy beyond absorption of silicon photovoltaics. These CQDs exhibit facets (nonpolar (100)) undisplayed in small-diameter CQDs; and the materials chemistry of smaller nanocrystals fails consequently to translate to materials for the short-wavelength IR regime. A new colloidal management strategy targeting the passivation of both (100) and (111) facets is demonstrated using distinct choices of cations and anions. The approach leads to narrow-bandgap CQDs with impressive colloidal stability and photoluminescence quantum yield. Photophysical studies confirm a reduction both in Stokes shift (≈47 meV) and Urbach tail (≈29 meV). This approach provides a ≈50% increase in the power conversion efficiency of IR photovoltaics compared to controls, and a ≈70% external quantum efficiency at their excitonic peak.

KW - colloidal quantum dots

KW - facet-specific passivation

KW - infrared solar cells

KW - narrow bandgap

KW - sodium acetate

UR - https://www.scopus.com/pages/publications/85062789296

U2 - 10.1002/adma.201805580

DO - 10.1002/adma.201805580

M3 - Article

C2 - 30860292

AN - SCOPUS:85062789296

SN - 0935-9648

VL - 31

JO - Advanced Materials

JF - Advanced Materials

IS - 17

M1 - 1805580

ER -

A Facet-Specific Quantum Dot Passivation Strategy for Colloid Management and Efficient Infrared Photovoltaics

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