Your search keyword '"Qin, Shucheng"' showing total 9 results

1. Giant Molecule Acceptor Enables Highly Efficient Organic Solar Cells Processed Using Non‐halogenated Solvent.

Author

Zhuo, Hongmei, Li, Xiaojun, Zhang, Jinyuan, Qin, Shucheng, Guo, Jing, Zhou, Ruimin, Jiang, Xin, Wu, Xiangxi, Chen, Zekun, Li, Jing, Meng, Lei, and Li, Yongfang

Subjects

SOLAR cells, CHARGE carrier mobility, SOLAR cell efficiency, MOLECULAR structure, SOLVENTS, PHOTOVOLTAIC power systems

Abstract

High efficiency organic solar cells (OSCs) based on A‐DA′D‐A type small molecule acceptors (SMAs) were mostly fabricated by toxic halogenated solvent processing, and power conversion efficiency (PCE) of the non‐halogenated solvent processed OSCs is mainly restricted by the excessive aggregation of the SMAs. To address this issue, we developed two vinyl π‐spacer linking‐site isomerized giant molecule acceptors (GMAs) with the π‐spacer linking on the inner carbon (EV‐i) or out carbon (EV‐o) of benzene end group of the SMA with longer alkyl side chains (ECOD) for the capability of non‐halogenated solvent‐processing. Interestingly, EV‐i possesses a twisted molecular structure but enhanced conjugation, while EV‐o shows a better planar molecular structure but weakened conjugation. The OSC with EV‐i as acceptor processed by the non‐halogenated solvent o‐xylene (o‐XY) demonstrated a higher PCE of 18.27 % than that of the devices based on the acceptor of ECOD (16.40 %) or EV‐o (2.50 %). 18.27 % is one of the highest PCEs among the OSCs fabricated from non‐halogenated solvents so far, benefitted from the suitable twisted structure, stronger absorbance and high charge carrier mobility of EV‐i. The results indicate that the GMAs with suitable linking site would be the excellent candidates for fabricating high performance OSCs processed by non‐halogenated solvents. [ABSTRACT FROM AUTHOR]

Published

2023

2. Giant Molecule Acceptor Enables Highly Efficient Organic Solar Cells Processed Using Non‐halogenated Solvent.

Author

Zhuo, Hongmei, Li, Xiaojun, Zhang, Jinyuan, Qin, Shucheng, Guo, Jing, Zhou, Ruimin, Jiang, Xin, Wu, Xiangxi, Chen, Zekun, Li, Jing, Meng, Lei, and Li, Yongfang

Subjects

SOLAR cells, CHARGE carrier mobility, SOLAR cell efficiency, MOLECULAR structure, SOLVENTS, PHOTOVOLTAIC power systems

Abstract

High efficiency organic solar cells (OSCs) based on A‐DA′D‐A type small molecule acceptors (SMAs) were mostly fabricated by toxic halogenated solvent processing, and power conversion efficiency (PCE) of the non‐halogenated solvent processed OSCs is mainly restricted by the excessive aggregation of the SMAs. To address this issue, we developed two vinyl π‐spacer linking‐site isomerized giant molecule acceptors (GMAs) with the π‐spacer linking on the inner carbon (EV‐i) or out carbon (EV‐o) of benzene end group of the SMA with longer alkyl side chains (ECOD) for the capability of non‐halogenated solvent‐processing. Interestingly, EV‐i possesses a twisted molecular structure but enhanced conjugation, while EV‐o shows a better planar molecular structure but weakened conjugation. The OSC with EV‐i as acceptor processed by the non‐halogenated solvent o‐xylene (o‐XY) demonstrated a higher PCE of 18.27 % than that of the devices based on the acceptor of ECOD (16.40 %) or EV‐o (2.50 %). 18.27 % is one of the highest PCEs among the OSCs fabricated from non‐halogenated solvents so far, benefitted from the suitable twisted structure, stronger absorbance and high charge carrier mobility of EV‐i. The results indicate that the GMAs with suitable linking site would be the excellent candidates for fabricating high performance OSCs processed by non‐halogenated solvents. [ABSTRACT FROM AUTHOR]

Published

2023

3. Terpolymer Donor with Inside Alkyl Substituents on Thiophene π‐Bridges toward Thiazolothiazole A2‐Unit Enables 18.21% Efficiency of Polymer Solar Cells.

Author

Zhou, Liuyang, Meng, Lei, Zhang, Jinyuan, Qin, Shucheng, Zhang, Jianqi, Li, Xiaojun, Li, Jing, Wei, Zhixiang, and Li, Yongfang

Subjects

THIOPHENES, SOLAR cell efficiency, FRONTIER orbitals, SOLAR cells, ELECTRON mobility

Abstract

PM6 is a widely used D–A copolymer donor in the polymer solar cells (PSCs). Incorporating second electron‐withdrawing (A2) units into PM6 backbone by ternary D–A1–D–A2 random copolymerization strategy is an effective approach to further improve its photovoltaic performance. Here, the authors synthesize the PM6‐based terpolymers by introducing thiazolothiazole as the A2 units connecting with thiophene π‐bridges attaching alkyl substituent towards the A2 unit (PMT‐CT) or towards D‐unit (PMT‐FT), and study the effect of the alkyl substituent position on the photovoltaic performance of them. Two terpolymers PMT‐FT‐10 and PMT‐CT‐10 are obtained by incorporating 10% A2 units in the terpolymers. The film of PMT‐CT‐10 shows slightly up‐shifted highest occupied molecular orbital (HOMO) energy levels while better co‐planar structure than that of PMT‐FT‐10. Meanwhile, the PMT‐CT‐10:Y6 blend film exhibits better molecular packing properties, more proper phase separation and more balanced hole and electron mobilities, which are beneficial to more efficient exciton dissociation, efficient charge transport and weaker bimolecular recombination. Consequently, the PMT‐CT‐10 based PSCs obtain the highest power conversion efficiency of 18.21%. The results indicate that side chain position on the thiophene π‐bridges influence the device performance of the terpolymer donors, and PMT‐CT‐10 is a high efficiency polymer donor for the PSCs. [ABSTRACT FROM AUTHOR]

Published

2022

4. High performance polymerized small molecule acceptor by synergistic optimization on π-bridge linker and side chain.

Author

Sun, Guangpei, Jiang, Xin, Li, Xiaojun, Meng, Lei, Zhang, Jinyuan, Qin, Shucheng, Kong, Xiaolei, Li, Jing, Xin, Jingming, Ma, Wei, and Li, Yongfang

Subjects

SMALL molecules, SOLAR cell efficiency, THIOPHENES, POLYMERS, CONJUGATED polymers, SOLAR cells, CHARGE transfer, PHASE separation

Abstract

The polymerized small-molecule acceptors have attracted great attention for application as polymer acceptor in all-polymer solar cells recently. The modification of small molecule acceptor building block and the π-bridge linker is an effective strategy to improve the photovoltaic performance of the polymer acceptors. In this work, we synthesized a new polymer acceptor PG-IT2F which is a modification of the representative polymer acceptor PY-IT by replacing its upper linear alkyl side chains on the small molecule building block with branched alkyl chains and attaching difluorene substituents on its thiophene π-bridge linker. Through this synergistic optimization, PG-IT2F possesses more suitable phase separation, increased charge transportation, better exciton dissociation, lower bimolecular recombination, and longer charge transfer state lifetime than PY-IT in their polymer solar cells with PM6 as polymer donor. Therefore, the devices based on PM6:PG-IT2F demonstrated a high power conversion efficiency of 17.24%, which is one of the highest efficiency reported for the binary all polymer solar cells to date. This work indicates that the synergistic regulation of small molecule acceptor building block and π-bridge linker plays a key role in designing and developing highly efficient polymer acceptors. The modification of small molecule acceptor building block and π−bridge linker is effective to improve photovoltaic performance. Here, the authors replace linear with branched alkyl chains and introduce difluorene-substituted linker to realise all-polymer solar cells with efficiency of 17.24%. [ABSTRACT FROM AUTHOR]

Published

2022

5. Introducing Low‐Cost Pyrazine Unit into Terpolymer Enables High‐Performance Polymer Solar Cells with Efficiency of 18.23%.

Author

Zhou, Liuyang, Meng, Lei, Zhang, Jinyuan, Zhu, Can, Qin, Shucheng, Angunawela, Indunil, Wan, Yan, Ade, Harald, and Li, Yongfang

Subjects

SOLAR cell efficiency, FRONTIER orbitals, PYRAZINES, POLYMERS, OPEN-circuit voltage, COPOLYMERS

Abstract

Recently, a random ternary copolymerization strategy has become a promising and efficient approach to develop high‐performance polymer donors for polymer solar cells (PSCs). In this study, a low‐cost electron‐withdrawing unit, 2,5‐bis(4‐(2‐ethylhexyl)thiophen‐2‐yl)pyrazine (PZ‐T), is incorporated into the polymer backbone of PM6 as the third component, and three D‐A1‐D‐A2 type terpolymers PMZ‐10, PMZ‐20, and PMZ‐30 are synthesized by the random copolymerization strategy, with the PZ‐T proportion of 10%, 20%, and 30%, respectively. The terpolymers exhibit downshifted highest occupied molecular orbital energy levels than PM6, which is beneficial for obtaining higher open‐circuit voltage (Voc) of the PSCs with the polymer as a donor. Importantly, the PSCs based on PMZ‐10:Y6 demonstrate efficient exciton dissociation, higher and balanced electron/hole mobilities, desirable aggregation, and high power conversion efficiency of 18.23%, which is the highest efficiency among the terpolymer‐based PSCs so far. The results indicate that the ternary copolymerization strategy with PZ‐T as the second A‐unit is an efficient approach to further improve the photovoltaic performance and reduce the synthetic cost of the D‐A copolymer donors. [ABSTRACT FROM AUTHOR]

Published

2022

6. Introducing Low‐Cost Pyrazine Unit into Terpolymer Enables High‐Performance Polymer Solar Cells with Efficiency of 18.23%.

Author

Zhou, Liuyang, Meng, Lei, Zhang, Jinyuan, Zhu, Can, Qin, Shucheng, Angunawela, Indunil, Wan, Yan, Ade, Harald, and Li, Yongfang

Subjects

SOLAR cell efficiency, FRONTIER orbitals, PYRAZINES, POLYMERS, COPOLYMERS, OPEN-circuit voltage

Abstract

Recently, a random ternary copolymerization strategy has become a promising and efficient approach to develop high‐performance polymer donors for polymer solar cells (PSCs). In this study, a low‐cost electron‐withdrawing unit, 2,5‐bis(4‐(2‐ethylhexyl)thiophen‐2‐yl)pyrazine (PZ‐T), is incorporated into the polymer backbone of PM6 as the third component, and three D‐A1‐D‐A2 type terpolymers PMZ‐10, PMZ‐20, and PMZ‐30 are synthesized by the random copolymerization strategy, with the PZ‐T proportion of 10%, 20%, and 30%, respectively. The terpolymers exhibit downshifted highest occupied molecular orbital energy levels than PM6, which is beneficial for obtaining higher open‐circuit voltage (Voc) of the PSCs with the polymer as a donor. Importantly, the PSCs based on PMZ‐10:Y6 demonstrate efficient exciton dissociation, higher and balanced electron/hole mobilities, desirable aggregation, and high power conversion efficiency of 18.23%, which is the highest efficiency among the terpolymer‐based PSCs so far. The results indicate that the ternary copolymerization strategy with PZ‐T as the second A‐unit is an efficient approach to further improve the photovoltaic performance and reduce the synthetic cost of the D‐A copolymer donors. [ABSTRACT FROM AUTHOR]

Published

2022

7. Polymerized small molecular acceptor based all-polymer solar cells with an efficiency of 16.16% via tuning polymer blend morphology by molecular design.

Author

Du, Jiaqi, Hu, Ke, Zhang, Jinyuan, Meng, Lei, Yue, Jiling, Angunawela, Indunil, Yan, Hongping, Qin, Shucheng, Kong, Xiaolei, Zhang, Zhanjun, Guan, Bo, Ade, Harald, and Li, Yongfang

Subjects

POLYMER blends, SOLAR cell efficiency, PHOTOVOLTAIC power systems, SOLAR cells, MOLECULAR structure, SMALL molecules, TRANSMISSION electron microscopy

Abstract

All-polymer solar cells (all-PSCs) based on polymerized small molecular acceptors (PSMAs) have made significant progress recently. Here, we synthesize two A-DA'D-A small molecule acceptor based PSMAs of PS-Se with benzo[c][1,2,5]thiadiazole A'-core and PN-Se with benzotriazole A'-core, for the studies of the effect of molecular structure on the photovoltaic performance of the PSMAs. The two PSMAs possess broad absorption with PN-Se showing more red-shifted absorption than PS-Se and suitable electronic energy levels for the application as polymer acceptors in the all-PSCs with PBDB-T as polymer donor. Cryogenic transmission electron microscopy visualizes the aggregation behavior of the PBDB-T donor and the PSMA in their solutions. In addition, a bicontinuous-interpenetrating network in the PBDB-T:PN-Se blend film with aggregation size of 10~20 nm is clearly observed by the photoinduced force microscopy. The desirable morphology of the PBDB-T:PN-Se active layer leads its all-PSC showing higher power conversion efficiency of 16.16%. Through development of non-fullerene acceptors, OPVs have reached efficiencies of 18%, yet the inadequate operational lifetime still poses a challenge for the commercialisation. Here, the authors investigate the origin of instability of NFA solar cells, and propose some strategies to mitigate this issue. [ABSTRACT FROM AUTHOR]

Published

2021

8. Non‐Halogenated‐Solvent Processed and Additive‐Free Tandem Organic Solar Cell with Efficiency Reaching 16.67%.

Author

Qin, Shucheng, Jia, Zhenrong, Meng, Lei, Zhu, Can, Lai, Wenbin, Zhang, Jinyuan, Huang, Wenchao, Sun, Chenkai, Qiu, Beibei, and Li, Yongfang

Subjects

PHOTOVOLTAIC power systems, SOLAR cell efficiency, SOLVENTS

Abstract

Organic solar cells (OSCs) have recently reached a remarkably high efficiency and become a promising technology for commercial application. However, OSCs with top efficiency are mostly processed by halogenated solvents and with additives that are not environmentally friendly, which hinders large‐scale manufacture. In this study, high‐performance tandem OSCs, based on polymer donors and two small‐molecule acceptors with different bandgaps, are fabricated by solution processing with non‐halogenated solvents without additive. Importantly, the two active layers developed from non‐halogenated solvents show better phase segregation and charge transport properties, leading to superior performance than halogenated ones. As a result, a tandem OSC with high efficiency of up to 16.67% is obtained, showing unique advantages in future massive production. [ABSTRACT FROM AUTHOR]

Published

2021

9. High performance tandem organic solar cells via a strongly infrared-absorbing narrow bandgap acceptor.

Author

Jia, Zhenrong, Qin, Shucheng, Meng, Lei, Ma, Qing, Angunawela, Indunil, Zhang, Jinyuan, Li, Xiaojun, He, Yakun, Lai, Wenbin, Li, Ning, Ade, Harald, Brabec, Christoph J., and Li, Yongfang

Subjects

SOLAR cells, SOLAR cell efficiency, PHOTOVOLTAIC power systems, ELECTRON donors, SHORT-circuit currents, DOUBLE bonds, OPEN-circuit voltage, ABSORPTION spectra

Abstract

Tandem organic solar cells are based on the device structure monolithically connecting two solar cells to broaden overall absorption spectrum and utilize the photon energy more efficiently. Herein, we demonstrate a simple strategy of inserting a double bond between the central core and end groups of the small molecule acceptor Y6 to extend its conjugation length and absorption range. As a result, a new narrow bandgap acceptor BTPV-4F was synthesized with an optical bandgap of 1.21 eV. The single-junction devices based on BTPV-4F as acceptor achieved a power conversion efficiency of over 13.4% with a high short-circuit current density of 28.9 mA cm−2. With adopting BTPV-4F as the rear cell acceptor material, the resulting tandem devices reached a high power conversion efficiency of over 16.4% with good photostability. The results indicate that BTPV-4F is an efficient infrared-absorbing narrow bandgap acceptor and has great potential to be applied into tandem organic solar cells. Development of tandem organic solar cells has been limited by the choice of near-infrared absorbing materials for the rear cell. Here, the authors report a simple strategy to extend the conjugation length of acceptor Y6 and broaden its absorption range to near-infrared region. A tandem organic solar cell with efficiency of 16.4% was achieved. [ABSTRACT FROM AUTHOR]

Published

2021