Education
  • 2011/09/10-2014/07/06
    中国科学院大学
    高分子化学与物理
  • 2003/09/13-2007/06/24
    湘潭大学
    高分子材料与工程
  • 2007/09/15-2010/06/18
    湘潭大学
    高分子化学与物理
Professional Experience
  • 2014-08 — 2022-06
    苏州大学
  • 2010-07 — 2011-08
    中国科学院化学研究所
  • 2018-01 — 2020-01
    香港理工大学
Publication
Papers

(1)Bing Guo. Fine-Tuned Active Layer Morphology for Bulk Heterojunction Organic Solar Cells with Indene-C60 Bisadduct as a Third Component .ACS Applied Materials & Interfaces .2023 ,15 (50):58693-58699

(2) Enhancing intermolecular packing and light harvesting through asymmetric non-fullerene acceptors for achieving 18.7% efficiency ternary organic solar cells .Journal of Materials Chemistry A .2023 ,11 (28):15553-15560

(3)Shi Yu. All-small-molecule Organic Solar Cells with Enhanced Efficiency and Stability Enabled by Polymer Additive as a Morphology Modulator .高 等 学 校 化 学 学 报 .2023 ,44 (7)

(4)Zhang, Liu. A Non-Halogenated Polymer Donor Based on Imide Unit for Organic Solar Cells with Efficiency Nearly 16% .Chinese Journal of Chemistry .2023 ,41 (17):2095-2102

(5)Xiao, Haiqin. An asymmetric non-fused electron-deficient building block for low-cost polymer acceptor in all-polymer solar cells .Science China-Chemistry .2023 ,66 (9):2626-2633

(6)Wu, Jingnan. Modulating the nanoscale morphology on carboxylate-pyrazine containing terpolymer toward 17.8% efficiency organic solar cells with enhanced thermal stability .Chemical Engineering Journal .2022 ,446

(7) Morphology optimization induced by a highly volatile solid additive contributes to efficient organic solar cells with enhanced photostability .Organic electronics .2024 ,125

(8)Qian, Deping. Correlating the Hybridization of Local-Exciton and Charge-Transfer States with Charge Generation in Organic Solar Cells .advanced energy materials .2023 ,13 (32)

(9)Xiao, Haiqin. An efficient polymer acceptor with fluorinated linkers enables all polymer solar cells with an efficiency of 15.7% .Journal of Materials Chemistry A .2023 ,11 (11):5584

(10)Zhang, Zhiliang. Enhancing intermolecular packing and light harvesting through asymmetric non-fullerene acceptors for achieving 18.7% efficiency ternary organic solar cells .Journal of Materials Chemistry A .2023 ,11 (28):15553

(11)杨顶. High-performance semitransparent organic solar cells enabled by pseudo-planar heterojunction structures combined with optical engineering .Journal of Materials Chemistry C .2022 (10(39))

(12)殷志红. Siloxane-functional small molecule acceptor for high-performance organic solar cells with 16.6% efficiency .Chemical Engineering Journal .2022 (442)

(13)燕欣. Highly efficient ternary solar cells with reduced non-radiative energy loss and enhanced stability via two compatible non-fullerene acceptors .Journal of Materials Chemistry A .2022 (10)

(14)王建邱. An asymmetric wide-bandgap acceptor simultaneously enabling highly efficient single-junction and tandem organic solar cells .Energy & Environmental Science .2022 (15)

(15)吕俊芳. A novel A–DA0D–A bifunctional small molecule for organic solar cell applications with impressive photovoltaic performance . Journal of Materials Chemistry A .2022 (31)

(16)肖海芹. An efficient polymer acceptor with fluorinated linkers enables all polymer solar cells with an efficiency of 15.7% .Journal of Materials Chemistry A .2023 (11)

(17)Haiyan Liang. 15.8% efficiency all-small-molecule solar cells enabled by a combination of side-chain engineering and polymer additive .Journal of Materials Chemistry A .2022 (2022, 10,)

(18)凡群平. High-performance nonfullerene polymer solar cells with open-circuit voltage over 1 V and energy loss as low as 0.54 eV .Nano Energy .2017 (40):20

(19)房进. Efficient As‐Cast Polymer Solar Cells with High and Stabilized Fill Factor .Solar RRL .2020 (10)

(20)宿文燕. Significant enhancement of the photovoltaic performance of organic small molecule acceptors via side-chain engineering .Journal of Materials Chemistry A .2018 (6):7988

(21)陈娟 . Highly efficient near-infrared and semitransparent polymer solar cells based on an ultra-narrow bandgap nonfullerene acceptor .Journal of Materials Chemistry A .2019 (7):3745

(22)国霞. A wide-bandgap polymer based on the alkylphenyl-substituted benzo[1,2-b:4,5-b′]dithiophene unit with high power conversion efficiency of over 11% .Journal of Materials Chemistry A .2018 (6):16529

(23)国霞. High Efficiency Nonfullerene Polymer Solar Cells with Thick Active Layer and Large Area .ADVANCED MATERIALS .2017 ,29 (36)

(24)郭青. Optimized molecular aggregation via incorporating fluorinated unit in the polymer donor for 17.3% efficiency organic solar cells .Chemical Engineering Journal .2021 (431)

(25)国霞. Optimized Active Layer Morphologies via Ternary Copolymerization of Polymer Donors for 17.6 % Efficiency Organic Solar Cells with Enhanced Fill Factor .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION .2022 (5):2322

(26)国霞. Selenium-containing Medium Bandgap Copolymer for Bulk Heterojunction Polymer Solar Cells with High Efficiency of 9.8% .CHEMISTRY OF MATERIALS Journal .2017 ,29 (11):4811

(27)郭冰. Exceeding 14% Efficiency for Solution-Processed Tandem Organic Solar Cells Combining Fullerene- and Nonfullerene-Based Subcells with Complementary Absorption .ACS ENERGY LETTERS .2018 (3)

Student Information
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