Progress in Materials, Solution Processes, and Long‐Term Stability for Large‐Area Organic Photovoltaics

Park, Sung Min; Kim, Tae-Hee; Yoon, Seongwon; Koh, Chang Woo; Woo, Han Young; Son, Hae Jung

doi:10.1002/adma.202002217

Cited by 137 publications

(103 citation statements)

References 211 publications

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“…[ 9–12 ] Recently, the power conversion efficiency (PCE) of all‐PSCs has been significantly boosted to over 15%, primarily due to the substantial efforts devoted to active‐layer material design, [ 13–17 ] device engineering, and bulk heterojunction morphology control, [ 18,19 ] demonstrating a great potential toward future practical application. [ 20,21 ]…”

Section: Introductionmentioning

confidence: 99%

Nonhalogenated‐Solvent‐Processed High‐Performance All‐Polymer Solar Cell with Efficiency over 14%

et al. 2021

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Rapid developments in material design have led to significant breakthroughs in the power conversion efficiency (PCE) of all‐polymer solar cells (all‐PSCs) in recent years. However, most of these devices are processed using halogenated solvents. Here, nonhalogenated solvent o‐xylene (o‐XY)‐processed all‐PSCs based on PBDB‐T:PJ1 are studied. Interestingly, it is found that the efficiency of the all‐PSCs can be greatly improved to 14.34% by simply increasing the spin‐coating speed during device processing. Careful studies reveal that this improvement could be attributed to the stronger centrifugal force (resulting from a higher spin‐coating speed), shorten the film formation time, and inhibit the excessive aggregation of PJ1. Consequently, a blend film with more reasonable domain size is formed. Based on these findings, another polymer acceptor PJ2, which bears a similar backbone to PJ1 but contains an additional thiophene spacer, is designed. PJ2 exhibits a much weaker aggregation ability and is used as a compatibilizer to improve the miscibility between the PBDB‐T and PJ1. Eventually, PBDB‐T:PJ1:PJ2‐based ternary all‐PSCs with a best PCE of 14.28% but processed under more mild conditions are obtained. These results may provide guidelines for future industrial fabrication of large‐area all‐PSCs.

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Section: Introductionmentioning

confidence: 99%

Nonhalogenated‐Solvent‐Processed High‐Performance All‐Polymer Solar Cell with Efficiency over 14%

et al. 2021

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“…9,10,325 It is noteworthy to mention that thin-film, lab-scale PePV and OPV with high efficiencies have been already obtained leading to record PCE values of 25.2% and 418%, respectively. [326][327][328][329][330][331] Intensive developments are continually being made for reducing the PCE gap between small and large-area modules, while achieving a high throughput, high stability, and minimum batch-to-batch variation, at lowest possible manufacturing cost. The atomically thin bodies and high flexibility of GRM make them the obvious choice to be integrated into PePV or OPV, serving as a complementary approach to Si for future-generation PV technology.…”

Section: Grm Enabled Pv Modules and Panels Towards On-grid Energy Generationmentioning

confidence: 99%

Up-scalable emerging energy conversion technologies enabled by 2D materials: from miniature power harvesters towards grid-connected energy systems

Rogdakis

Karakostas

Kymakis

2021

Energy Environ. Sci.

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“…[43,[50][51][52][53] Other challenges concerns the development of new molecularly engineered donor and acceptor materials that can exhibit a high efficiency when formed into thick active layers (desirable for upscaling). [42,43,54,55] These challenges have been previously rev iewed, [42,43,50,54,56] including some very recent reviews, [42,43,50,54] and will not be the subject of specific attention here.…”

Section: Introductionmentioning

confidence: 99%

Progress in Upscaling Organic Photovoltaic Devices

Bernardo

Lopes

Lidzey

et al. 2021

Advanced Energy Materials

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Organic photovoltaic (OPV) cells have recently undergone a rapid increase in power conversion efficiency (PCE) under AM1.5G conditions, as certified by the National Renewable Energy Laboratory (NREL), which have jumped from 11.5% in October 2017 to 18.2% in December 2020. However, the NREL certified PCE of large area OPV modules is still lagging far behind (11.7% in July 2020). Additionally, there has been a rapidly growing interest in the use of OPVs for dim light indoor applications, with reported PCE of some large area (≥1 cm2) devices, under 1000 lux, well above 20%. The transition of OPV from the lab to the market requires the development of effective manufacturing processes that can scale‐up laboratory‐scale devices into large area devices, without sacrificing performance and simultaneously minimizing associated manufacturing costs. This review article focuses on four important challenges that OPV technology has to face to achieve a reliable lab‐to‐fab transfer, namely: i) The upscaling of indium‐tin‐oxide (ITO)‐based single cells and the interconnection of single cells into large area modules; ii) the development of alternatives to vacuum processing; iii) the development of alternatives to ITO‐based substrates; and iv) strategies for improving the lifetime of large area OPV devices.

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Progress in Materials, Solution Processes, and Long‐Term Stability for Large‐Area Organic Photovoltaics

Cited by 137 publications

References 211 publications

Nonhalogenated‐Solvent‐Processed High‐Performance All‐Polymer Solar Cell with Efficiency over 14%

Nonhalogenated‐Solvent‐Processed High‐Performance All‐Polymer Solar Cell with Efficiency over 14%

Up-scalable emerging energy conversion technologies enabled by 2D materials: from miniature power harvesters towards grid-connected energy systems

Progress in Upscaling Organic Photovoltaic Devices

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