Size dependence of carrier dynamics and carrier multiplication in PbS quantum dots

Nootz, Gero; Padilha, Lázaro A.; Levina, Larissa; Sukhovatkin, Vlad; Webster, Scott; Brzozowski, Lukasz; Sargent, Edward H.; Hagan, David J.; Stryland, Eric W. Van

doi:10.1103/physrevb.83.155302

Cited by 56 publications

(88 citation statements)

References 38 publications

(91 reference statements)

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“…In this Article, we show that for thin PbS nanosheets of 4 nm thickness, the photon energy in excess of the CM threshold is virtually completely used to produce additional e–h pairs, in contrast to quantum dots (zero-dimensional, 0D)11121314, nanorods (one-dimensional, 1D)151617 and bulk (three-dimensional, 3D)18. The threshold energy of CM in PbS nanosheets with thickness in the range 4–7 nm is near 3 eV.…”

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confidence: 99%

Highly efficient carrier multiplication in PbS nanosheets

et al. 2014

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Semiconductor nanocrystals are promising for use in cheap and highly efficient solar cells. A high efficiency can be achieved by carrier multiplication (CM), which yields multiple electron-hole pairs for a single absorbed photon. Lead chalcogenide nanocrystals are of specific interest, since their band gap can be tuned to be optimal to exploit CM in solar cells. Interestingly, for a given photon energy CM is more efficient in bulk PbS and PbSe, which has been attributed to the higher density of states. Unfortunately, these bulk materials are not useful for solar cells due to their low band gap. Here we demonstrate that two-dimensional PbS nanosheets combine the band gap of a confined system with the high CM efficiency of bulk. Interestingly, in thin PbS nanosheets virtually the entire excess photon energy above the CM threshold is used for CM, in contrast to quantum dots, nanorods and bulk lead chalcogenide materials.

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confidence: 99%

Highly efficient carrier multiplication in PbS nanosheets

et al. 2014

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“…44,45 Furthermore, the lifetime of the photoexcited electron in the Ag 2 S QD is about 1or 2 orders of magnitude longer than those of comparable size PbS QD or single-walled carbon nanotubes, respectively 25 , which suggest that the K TR » K Re in the Ag 2 S QD layer. 48,18 Clark et al also found the electron lifetime of PbS and PbSe QDs were 2 orders of magnitude longer than the CdS and CdSe QDs, however, they had 9 similar electron injection rate. 47 When the PbS QD size was more than 4.8 nm, the electron injection was not expected because the E g of QD was too narrow with size increasing.…”

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confidence: 97%

Efficient charge-carrier extraction from Ag₂S quantum dots prepared by the SILAR method for utilization of multiple exciton generation

2015

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The utilization of electron-hole pairs (EHPs) generated from multiple excitons in quantum dots (QDs) is of great interest toward efficient photovoltaic devices and other optoelectronic devices; however, extraction of charge carriers remains difficult. Herein, we extract photocharges from Ag2S QDs and investigate the dependence of the electric field on the extraction of charges from multiple exciton generation (MEG). Low toxic Ag2S QDs are directly grown on TiO2 mesoporous substrates by employing the successive ionic layer adsorption and reaction (SILAR) method. The contact between QDs is important for the initial charge separation after MEG and for the carrier transport, and the space between neighbor QDs decreases with more SILAR cycles, resulting in better charge extraction. At the optimal electric field for extraction of photocharges, the results suggest that the threshold energy (hνth) for MEG is 2.41Eg. The results reveal that Ag2S QD is a promising material for efficient extraction of charges from MEG and that QDs prepared by SILAR have an advantageous electrical contact facilitating charge separation and extraction.

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“…via an Auger process). In lead chalcogenide QDs, the latter process proceeds on 20−200 ps time scales [51,124]. As mentioned previously, charge separation can be at least two orders of magnitude faster if an ionising interface is in close proximity to the generated exciton [110].…”

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confidence: 83%

Multiple exciton generation in quantum dot-based solar cells

et al. 2017

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Multiple exciton generation (MEG) in quantumconfined semiconductors is the process by which multiple bound charge-carrier pairs are generated after absorption of a single high-energy photon. Such charge-carrier multiplication effects have been highlighted as particularly beneficial for solar cells where they have the potential to increase the photocurrent significantly. Indeed, recent research efforts have proved that more than one chargecarrier pair per incident solar photon can be extracted in photovoltaic devices incorporating quantum-confined semiconductors. While these proof-of-concept applications underline the potential of MEG in solar cells, the impact of the carrier multiplication effect on the device performance remains rather low. This review covers recent advancements in the understanding and application of MEG as a photocurrent-enhancing mechanism in quantum dot-based photovoltaics.

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Size dependence of carrier dynamics and carrier multiplication in PbS quantum dots

Cited by 56 publications

References 38 publications

Highly efficient carrier multiplication in PbS nanosheets

Highly efficient carrier multiplication in PbS nanosheets

Efficient charge-carrier extraction from Ag₂S quantum dots prepared by the SILAR method for utilization of multiple exciton generation

Multiple exciton generation in quantum dot-based solar cells

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Size dependence of carrier dynamics and carrier multiplication in PbS quantum dots

Cited by 56 publications

References 38 publications

Highly efficient carrier multiplication in PbS nanosheets

Highly efficient carrier multiplication in PbS nanosheets

Efficient charge-carrier extraction from Ag2S quantum dots prepared by the SILAR method for utilization of multiple exciton generation

Multiple exciton generation in quantum dot-based solar cells

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Efficient charge-carrier extraction from Ag₂S quantum dots prepared by the SILAR method for utilization of multiple exciton generation