Infrared
(IR) solar cells are promising devices for significantly
improving the power conversion efficiency of common solar cells by
harvesting the low-energy IR photons. PbSe quantum dots (QDs) are
superior IR photon absorbing materials due to their strong quantum
confinement and thus strong interdot electronic coupling. However,
the high chemical activity of PbSe QDs leads to etching and poor passivation
in ligand exchange, resulting in a high trap-state density and a high
open circuit voltage (V
OC) deficit. Here
we develop a hybrid ligand co-passivation strategy to simultaneously
passivate the Pb and Se sites; that is, halide anions passivate the
Pb sites and Cd cations passivate the Se sites. The cation and anion
hybrid passivation substantially improves the quality of PbSe QD solids,
giving rise to an excellent trap-state control and prolonged carrier
lifetime. A high V
OC and a high short
circuit current density (J
SC) are achieved
simultaneously in the IR QD solar cells based on this hybrid ligand
treatment. Finally, a IR-PCE of 1.31% under the 1100-nm-filtered solar
illumination is achieved in the PbSe QD solar cells, which is the
highest IR-PCE for PbSe QD IR solar cells at present. Additionally,
the PbSe QD devices show a high external quantum efficiency of 80%
at ∼1295 nm.
Infrared solar cells (IRSCs) can supplement silicon or perovskite SCs to broaden the utilization of the solar spectrum. As an ideal infrared photovoltaic material, PbS colloidal quantum dots (CQDs) with tunable bandgaps can make good use of solar energy, especially the infrared region. However, as the QD size increases, the energy level shrinking and surface facet evolution makes us reconsider the matching charge extraction contacts and the QD passivation strategy. Herein, different to the traditional sol‐gel ZnO layer, energy‐level aligned ZnO thin film from a magnetron sputtering method is adopted for electron extraction. In addition, a modified hybrid ligand recipe is developed for the facet passivation of large size QDs. As a result, the champion IRSC delivers an open circuit voltage of 0.49 V and a power conversion efficiency (PCE) of 10.47% under AM1.5 full‐spectrum illumination, and the certified PCE is over 10%. Especially the 1100 nm filtered efficiency achieves 1.23%. The obtained devices also show high storage stability. The present matched electron extraction and QD passivation strategies are expected to highly booster the IR conversion yield and promote the fast development of new conception QD optoelectronics.
Lead chalcogenide quantum dot (QD) infrared (IR) solar cells are promising devices for breaking through the theoretical efficiency limit of single‐junction solar cells by harvesting the low‐energy IR photons that cannot be utilized by common devices. However, the device performance of QD IR photovoltaic is limited by the restrictive relation between open‐circuit voltages (VOC) and short circuit current densities (JSC), caused by the contradiction between surface passivation and electronic coupling of QD solids. Here, a strategy is developed to decouple this restriction via epitaxially coating a thin PbS shell over the PbSe QDs (PbSe/PbS QDs) combined with in situ halide passivation. The strong electronic coupling from the PbSe core gives rise to significant carrier delocalization, which guarantees effective carrier transport. Benefited from the protection of PbS shell and in situ halide passivation, excellent trap‐state control of QDs is eventually achieved after the ligand exchange. By a fine control of the PbS shell thickness, outstanding IR JSC of 6.38 mA cm−2 and IR VOC of 0.347 V are simultaneously achieved under the 1100 nm‐filtered solar illumination, providing a new route to unfreeze the trade‐off between VOC and JSC limited by the photoactive layer with a given bandgap.
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