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Multibandgap quantum dot ensembles for solar-matched infrared energy harvesting

by Saidaminov, Makhsud I. , Tan, Furui , Tan, Hairen , García de Arquer, F. Pelayo , Liu, Mengxia , Xu, Jixian , Lu, Zheng Hong , Kelley, Shana O. , Jo, Jea Woong , Hoogland, Sjoerd , Sun, Bin , Li, Peicheng , Voznyy, Oleksandr , Kim, Younghoon , Proppe, Andrew H. , Ouellette, Olivier , Sargent, Edward H. , Fan, James Z. , Wei, Mingyang

in 140/146 / 147/135 / 639/4077/909/4101/4096/946 / 639/624/399/1017 / Circuits / Density of states / Efficiency / Energy conversion efficiency / Energy harvesting / Humanities and Social Sciences / Infrared radiation / Lead sulfides / multidisciplinary / Open circuit voltage / Photoelectric effect / Photoelectric emission / Photons / Photovoltaic cells / Quantum dots / Quantum efficiency / Science / Science (multidisciplinary) / Short circuit currents / Short-circuit current / Silicon / Solar cells / Solar energy / Sulfides / Voltage

2018

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2018

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2018

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Journal Article

Multibandgap quantum dot ensembles for solar-matched infrared energy harvesting

Saidaminov, Makhsud I.,

Tan, Furui,

Tan, Hairen,

García de Arquer, F. Pelayo,

Liu, Mengxia,

Xu, Jixian,

Lu, Zheng Hong,

Kelley, Shana O.,

Jo, Jea Woong,

Hoogland, Sjoerd,

Sun, Bin,

Li, Peicheng,

Voznyy, Oleksandr,

Kim, Younghoon,

Proppe, Andrew H.,

Ouellette, Olivier,

Sargent, Edward H.,

Fan, James Z.,

Wei, Mingyang

2018

Overview

As crystalline silicon solar cells approach in efficiency their theoretical limit, strategies are being developed to achieve efficient infrared energy harvesting to augment silicon using solar photons from beyond its 1100 nm absorption edge. Herein we report a strategy that uses multi-bandgap lead sulfide colloidal quantum dot (CQD) ensembles to maximize short-circuit current and open-circuit voltage simultaneously. We engineer the density of states to achieve simultaneously a large quasi-Fermi level splitting and a tailored optical response that matches the infrared solar spectrum. We shape the density of states by selectively introducing larger-bandgap CQDs within a smaller-bandgap CQD population, achieving a 40 meV increase in open-circuit voltage. The near-unity internal quantum efficiency in the optimized multi-bandgap CQD ensemble yielded a maximized photocurrent of 3.7 ± 0.2 mA cm −2 . This provides a record for silicon-filtered power conversion efficiency equal to one power point, a 25% (relative) improvement compared to the best previously-reported results. Efficient harvest of solar energy beyond the silicon absorption edge of 1100 nm by semiconductor solar cells remains a challenge. Here Sun et al. mix high multi-bandgap lead sulfide colloidal quantum dot ensembles to further increase both short circuit current and open circuit voltage.

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Publisher

Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio

Subject

140/146

/ 147/135

/ 639/4077/909/4101/4096/946