Quantitative Analysis of Trap-State-Mediated Exciton Transport in Perovskite-Shelled PbS Quantum Dot Thin Films Using Photocarrier Diffusion-Wave Nondestructive Evaluation and Imaging

Hu, Lilei; Yang, Zhenyu; Mandelis, Andreas; Melnikov, Alexander; Lan, Xinzheng; Walters, Grant; Hoogland, Sjoerd; Sargent, Edward H.

doi:10.1021/acs.jpcc.6b04468

Cited by 27 publications

(17 citation statements)

References 72 publications

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“…The TA spectra of the MAPbI3/QDs and Consequently, the blue shift in the PB2 band of MAPbI3/QDs is due to changes in the electronic and/or crystallographic structure of MAPbI3 in presence of the QDs. Such modifications were observed after passivation by the QDs due to the lattice mismatch between the two materials [18,21,44,45]. The interpretation of the blue shift also agrees with reported band gap expansion of MAPbI3 related to structural deformation [46].…”

Section: Transient Spectra and Decayssupporting

confidence: 87%

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Perovskite-quantum dots interface: Deciphering its ultrafast charge carrier dynamics

et al. 2018

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Understanding electron and hole (e,h) transport at semiconductor interfaces is paramount to developing efficient optoelectronic devices. Halide perovskite/semiconductor quantum dots (QDs) have emerged as smart hybrid systems with a huge potential for light emission and energy conversion. However, the dynamics of generated e-h pairs are not fully understood. Ultrafast UV-VIS transient absorption and THz spectroscopies have enabled us to unravel the processes of the e-h recombination within a hybrid film of methylammonium lead triiodide (MAPbI3) interacting with different amount of PbS/CdS core/shell QDs. To accurately analyse the complex behaviour, we applied a new model for e-h events in this hybrid material. The results obtained with sample having a high concentration of QDs (7.3 mass percentage) indicate: (i) a large population (92%) of the photogenerated charge carriers are affected by QDs presence. The main part of these carriers (85% of the total) in perovskite domain diffuse towards QDs, where they transfer to the interface (electrons) and QD´s valence bands (holes) with rate constants of 1.2×10 10 s-1 and 4.6×10 10 s-1 , respectively. 7% of these affected charged entities 2 are excitons in the perovskite domain in close vicinity of the interface, and show a recombination rate constant of 3.7×10 10 s-1. (ii) The carriers not affected by QDs presence (8%) recombine through known perovskite deactivation channels. Lowering the QDs mass percentage to 0.24 causes a decrease of electron and hole effective transfer rate constants, and disappearance of excitons. These results provide clues to improve the performance of perovskite/QD based devices.

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Section: Transient Spectra and Decayssupporting

confidence: 87%

“…Thirdly, electrons can be transferred and subsequently trapped in perovskite/QDs interface. Indeed, it has been reported that, in the presence of QDs, the crystallographic structure of the MAPbI3 lattice might be different inside the crystallite and at the interface with the QDs, thus, new trap states will appear [18,21,44].…”

Section: Description Of the Modelmentioning

confidence: 99%

Perovskite-quantum dots interface: Deciphering its ultrafast charge carrier dynamics

et al. 2018

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“…A better electrode coating with lower interface states leads to low S ( d ) that results in higher CQDSC performance. To investigate the CQD/Au interface effects on CQDSC performance, nondestructive imaging (NDI) of carrier population distributions and key photovoltaic parameters was conducted using LIC, a spectrally gated dynamic frequency‐domain photoluminescence‐based transport property imaging method . The LIC images revealed the complexity and inhomogeneity of the electrode‐coating‐associated surface recombination in our experimental CQDSCs.…”

Section: Resultsmentioning

confidence: 99%

“…Furthermore, the calibration for spectral mismatch was conducted using a reference solar cell (Newport). Finally, following our previously reported method, LIC imaging of the CQDSCs was performed in a room‐temperature nitrogen environment under 10 Hz modulation frequency.…”

Section: Solar Cell Fabrication and Efficiency Optimizationmentioning

confidence: 99%

“…Colloidal quantum dot solar cells (CQDSCs) are presently attracting immense research interest on a global scale due to the meteoric rise of their solar to electric power conversion efficiency (PCE) from 3% to 13.4% within a period of only 7 years . Intensive efforts are underway to boost CQDSC PCE through device architecture engineering, surface materials chemistry, synthesis methodologies, charge carrier dynamics, and theoretical modeling . However, no comprehensive device efficiency optimization strategies have been reported aiming at achieving higher PCE, specifically for CQDSCs.…”

Section: Introductionmentioning

confidence: 99%

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Colloidal quantum dot solar cell power conversion efficiency optimization using analysis of current‐voltage characteristics and electrode contact imaging by lock‐in carrierography

Liu

Mandelis

et al. 2017

Progress in Photovoltaics

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Although the power conversion efficiency (PCE) of colloidal quantum dot solar cells (CQDSCs) has increased sharply, researchers are struggling with the lack of comprehensive device efficiency optimization strategies, which retards significant progress in CQDSC improvement. This paper addresses this critical issue through analyzing the impact of colloidal quantum dot (CQD) carrier hopping mobility, bandgap energy, illumination intensity, and electrode/CQD interface on device performance to develop a guiding criterion for CQDSC PCE optimization. This general strategy has been used for the successful fabrication of high-efficiency CQDSCs yielding certified PCEs as high as 11.28 %. A major experimental finding of this work is that the widely used constant photocurrent density (J ph ) assumption is invalid as J ph is external-voltage dependent due to the low carrier hopping mobility. Furthermore, the theoretical model developed herein predicts the nonmonotonic dependence of CQDSC PCE on carrier hopping mobility and bandgap energy, which were also demonstrated with the high-efficiency CQDSCs. These results constitute a revision basis of the widespread belief that higher mobility and lower bandgap energy correspond to a higher CQDSC efficiency. Furthermore, electrode/CQD interfacedependent surface recombination velocities were investigated in the framework of our abovementioned theoretical model using lock-in carrierography, a contactless, large-area frequency-domain photocarrier diffusion-wave imaging methodology that elucidated the carrier collection process at the electrodes through open-circuit voltage distribution imaging.Lock-in carrierography eliminates the limitations of today's widely used small-spot (<0.1 cm 2 ) testing methods which, however, raise questionable overall solar cell performance and stability estimations. KEYWORDS bandgap energy, colloidal quantum dot solar cell, electrode-semiconductor interface, hopping mobility, large-area imaging, lock-in carrierography 1 | INTRODUCTION Colloidal quantum dot solar cells (CQDSCs) are presently attracting immense research interest on a global scale due to the meteoric rise of their solar to electric power conversion efficiency (PCE) from 3% to 13.4% within a period of only 7 years. 1 Intensive efforts are underway to boost CQDSC PCE through device architecture engineering, 2-4 surface materials chemistry, 5-7 synthesis methodologies, 8,9 charge carrier dynamics, 10-17 and theoretical modeling. 18-20 However, no comprehensive device efficiency optimization strategies have been reported aiming at achieving higher PCE, specifically for CQDSCs.Researchers use common sense approaches instead, trying to improve CQDSC efficiency through pursuing higher carrier mobility using disparate surface passivation materials and increasing quantum dot size for lower bandgap energy to harvest the solar spectrum in a wider wavelength range. This universal strategy, however, is typically valid for conventional solar cells of high carrier mobility such as Si solar cells, rather t...

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Passivating {100} Facets of PbS Colloidal Quantum Dots via Perovskite Bridges for Sensitive and Stable Infrared Photodiodes

Chen

Liu

Xia

et al. 2022

Adv Funct Materials

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Solution‐processed PbS colloidal quantum dots (CQDs) are promising optoelectronic materials for next‐generation infrared imagers due to their monolithic integratability with silicon readout circuit and tunable bandgap controlled by CQDs size. However, large‐size PbS CQDs (diameter >4 nm) for longer shortwave‐infrared photodetection consist mainly of {100} facets with incomplete surface passivation and unsatisfied stability. Here, it is reported that perovskite‐bridged PbS CQDs, in which the {100} facets of the CQDs are epitaxially bridged with CsPbI3–xBrx perovskite, can achieve improved passivation and enhanced stability in comparison with the traditional strategies. The resultant infrared CQDs photodiodes exhibit significantly reduced dark current, nearly 50% enhanced photoresponse, and improved work stability. These superior properties synergistically produce the most balanced performance (with a high −3 dB bandwidth of 42 kHz and an impressive specific detectivity of 6.2 × 1012 Jones) among the reported CQDs photodetectors.

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Quantitative Analysis of Trap-State-Mediated Exciton Transport in Perovskite-Shelled PbS Quantum Dot Thin Films Using Photocarrier Diffusion-Wave Nondestructive Evaluation and Imaging

Cited by 27 publications

References 72 publications

Perovskite-quantum dots interface: Deciphering its ultrafast charge carrier dynamics

Perovskite-quantum dots interface: Deciphering its ultrafast charge carrier dynamics

Colloidal quantum dot solar cell power conversion efficiency optimization using analysis of current‐voltage characteristics and electrode contact imaging by lock‐in carrierography

Passivating {100} Facets of PbS Colloidal Quantum Dots via Perovskite Bridges for Sensitive and Stable Infrared Photodiodes

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