Micron Thick Colloidal Quantum Dot Solids

James Z. Fan; Maral Vafaie; Koen Bertens; Mykhailo Sytnyk; Joao M. Pina; Laxmi Kishore Sagar; Olivier Ouellette; Andrew H. Proppe; Armin Sedighian Rasouli; Yajun Gao; Se Woong Baek; Bin Chen; Frédéric Laquai; Sjoerd Hoogland; F. Pelayo García De Arquer; Wolfgang Heiss; Edward H. Sargent

doi:10.1021/acs.nanolett.0c01614

Micron Thick Colloidal Quantum Dot Solids

James Z. Fan
, Maral Vafaie
, Koen Bertens
, Mykhailo Sytnyk
, Joao M. Pina
, Laxmi Kishore Sagar
, Olivier Ouellette
, Andrew H. Proppe
, Armin Sedighian Rasouli
, Yajun Gao
, Se Woong Baek
, Bin Chen
, Frédéric Laquai
, Sjoerd Hoogland
, F. Pelayo García De Arquer
, Wolfgang Heiss
, Edward H. Sargent^*

^*Corresponding author for this work

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

62 Citations (Scopus)

Abstract

Shortwave infrared colloidal quantum dots (SWIR-CQDs) are semiconductors capable of harvesting across the AM1.5G solar spectrum. Today's SWIR-CQD solar cells rely on spin-coating; however, these films exhibit cracking once thickness exceeds ∼500 nm. We posited that a blade-coating strategy could enable thick QD films. We developed a ligand exchange with an additional resolvation step that enabled the dispersion of SWIR-CQDs. We then engineered a quaternary ink that combined high-viscosity solvents with short QD stabilizing ligands. This ink, blade-coated over a mild heating bed, formed micron-thick SWIR-CQD films. These SWIR-CQD solar cells achieved short-circuit current densities (Jsc) that reach 39 mA cm-2, corresponding to the harvest of 60% of total photons incident under AM1.5G illumination. External quantum efficiency measurements reveal both the first exciton peak and the closest Fabry-Perot resonance peak reaching approximately 80% - this is the highest unbiased EQE reported beyond 1400 nm in a solution-processed semiconductor.

Original language	English
Pages (from-to)	5284-5291
Number of pages	8
Journal	Nano Letters
Volume	20
Issue number	7
DOIs	https://doi.org/10.1021/acs.nanolett.0c01614
Publication status	Published - 2020 Jul 8
Externally published	Yes

Bibliographical note

Publisher Copyright:
Copyright © 2020 American Chemical Society.

Keywords

blade coating
infrared photovoltaics
ligand exchange
quantum dots

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

Access to Document

10.1021/acs.nanolett.0c01614

Cite this

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title = "Micron Thick Colloidal Quantum Dot Solids",

abstract = "Shortwave infrared colloidal quantum dots (SWIR-CQDs) are semiconductors capable of harvesting across the AM1.5G solar spectrum. Today's SWIR-CQD solar cells rely on spin-coating; however, these films exhibit cracking once thickness exceeds ∼500 nm. We posited that a blade-coating strategy could enable thick QD films. We developed a ligand exchange with an additional resolvation step that enabled the dispersion of SWIR-CQDs. We then engineered a quaternary ink that combined high-viscosity solvents with short QD stabilizing ligands. This ink, blade-coated over a mild heating bed, formed micron-thick SWIR-CQD films. These SWIR-CQD solar cells achieved short-circuit current densities (Jsc) that reach 39 mA cm-2, corresponding to the harvest of 60\% of total photons incident under AM1.5G illumination. External quantum efficiency measurements reveal both the first exciton peak and the closest Fabry-Perot resonance peak reaching approximately 80\% - this is the highest unbiased EQE reported beyond 1400 nm in a solution-processed semiconductor.",

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year = "2020",

month = jul,

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doi = "10.1021/acs.nanolett.0c01614",

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AU - Fan, James Z.

AU - Vafaie, Maral

AU - Bertens, Koen

AU - Sytnyk, Mykhailo

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AU - Sagar, Laxmi Kishore

AU - Ouellette, Olivier

AU - Proppe, Andrew H.

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AU - Gao, Yajun

AU - Baek, Se Woong

AU - Chen, Bin

AU - Laquai, Frédéric

AU - Hoogland, Sjoerd

AU - Arquer, F. Pelayo García De

AU - Heiss, Wolfgang

AU - Sargent, Edward H.

PY - 2020/7/8

Y1 - 2020/7/8

N2 - Shortwave infrared colloidal quantum dots (SWIR-CQDs) are semiconductors capable of harvesting across the AM1.5G solar spectrum. Today's SWIR-CQD solar cells rely on spin-coating; however, these films exhibit cracking once thickness exceeds ∼500 nm. We posited that a blade-coating strategy could enable thick QD films. We developed a ligand exchange with an additional resolvation step that enabled the dispersion of SWIR-CQDs. We then engineered a quaternary ink that combined high-viscosity solvents with short QD stabilizing ligands. This ink, blade-coated over a mild heating bed, formed micron-thick SWIR-CQD films. These SWIR-CQD solar cells achieved short-circuit current densities (Jsc) that reach 39 mA cm-2, corresponding to the harvest of 60% of total photons incident under AM1.5G illumination. External quantum efficiency measurements reveal both the first exciton peak and the closest Fabry-Perot resonance peak reaching approximately 80% - this is the highest unbiased EQE reported beyond 1400 nm in a solution-processed semiconductor.

AB - Shortwave infrared colloidal quantum dots (SWIR-CQDs) are semiconductors capable of harvesting across the AM1.5G solar spectrum. Today's SWIR-CQD solar cells rely on spin-coating; however, these films exhibit cracking once thickness exceeds ∼500 nm. We posited that a blade-coating strategy could enable thick QD films. We developed a ligand exchange with an additional resolvation step that enabled the dispersion of SWIR-CQDs. We then engineered a quaternary ink that combined high-viscosity solvents with short QD stabilizing ligands. This ink, blade-coated over a mild heating bed, formed micron-thick SWIR-CQD films. These SWIR-CQD solar cells achieved short-circuit current densities (Jsc) that reach 39 mA cm-2, corresponding to the harvest of 60% of total photons incident under AM1.5G illumination. External quantum efficiency measurements reveal both the first exciton peak and the closest Fabry-Perot resonance peak reaching approximately 80% - this is the highest unbiased EQE reported beyond 1400 nm in a solution-processed semiconductor.

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KW - ligand exchange

KW - quantum dots

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Micron Thick Colloidal Quantum Dot Solids

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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