2023

[226] The central core size effect in quinoxaline-based non-fullerene acceptors for high V OC organic solar cells. Ran, X., Shi, Y., Qiu, D., Zhang, J., Lu, K., and Wei, Z. Nanoscale, 15(45), 18291-18299.

[227] Central Core Substitutions and Film‐Formation Process Optimization Enable Approaching 19% Efficiency All‐Polymer Solar Cells. Qiu, D., Zhang, H., Tian, C., Zhang, J., Zhu, L., Wei, Z., and Lu, K. Advanced Materials, 35(51), 2307398.

[228] Co-Intercalation-Free Ether-Based Weakly Solvating Electrolytes Enable Fast-Charging and Wide-Temperature Lithium-Ion Batteries. Wang, Z., Han, R., Huang, D., Wei, Y., Song, H., Liu, Y., Xue, J., Zhang, H., Zhang, F., and Liu, L. ACS nano, 17(18), 18103-18113.

[229] Concretized structural evolution supported assembly-controlled film-forming kinetics in slot-die coated organic photovoltaics. Zhang, H., Tian, C., Zhang, Z., Xie, M., Zhang, J., Zhu, L., and Wei, Z. Nature Communications, 14(1), 6312.

[230] Conjugation expansion strategy enables highly stable all-polymer solar cells. Qiu, D., Shi, Y., Li, Y., Zhang, J., Lu, K., and Wei, Z. Chinese Chemical Letters, 34(8), 108019.

[231] Efficient Large Area All‐Small‐Molecule Organic Solar Cells Fabricated by Slot‐Die Coating with Nonhalogen Solvent. Liu, Y., Zhang, J., Tian, C., Shen, Y., Wang, T., Zhang, H., He, C., Qiu, D., Shi, Y., and Wei, Z. Advanced Functional Materials, 33(32), 2300778.

[232] Enhanced photovoltaic performance of PM6/Y6-based organic solar cells by a wide-bandgap small molecule acceptor. Yang, S., Pan, J., Wu, S., Luo, D., Shen, X., Peng, F., and Zhang, Y. Journal of Nanoparticle Research, 25(7), 134.

[233] Fused‐Ring Electron‐Acceptor Single Crystals with Chiral 2D Supramolecular Organization for Anisotropic Chiral Optoelectronic Devices. Liu, L., Yang, Y., Meskers, S. C., Wang, Q., Zhang, L., Yang, C., Zhang, J., Zhu, L., Zhang, Y., and Wei, Z. Advanced Materials, 35(45), 2304627.

[234] Halogenated thiophene substitutions on quinoxaline unit to achieve morphology optimization in efficient organic solar cells. Qiu, D., Zhang, J., Lu, K., and Wei, Z. Nano Research, 16(9), 11630-11637.

[235] Improving the efficiency of ternary organic solar cells by reducing energy loss. Wang, M., Shi, Y., Zhang, Z., Shen, Y., Lv, M., Yan, Y., Zhou, H., Zhang, J., Lv, K., and Zhang, Y. Nanoscale Horizons, 8(8), 1073-1081.

[236] In situ absorption characterization guided slot‐die‐coated high‐performance large‐area flexible organic solar cells and modules. Shen, Y. F., Zhang, H., Zhang, J., Tian, C., Shi, Y., Qiu, D., Zhang, Z., Lu, K., and Wei, Z. Advanced Materials, 35(10), 2209030.

[237] In situ performance and stability tests of large-area flexible polymer solar cells in the 35-km stratospheric environment. Xu, Z., Xu, G., Luo, Q., Han, Y., Tang, Y., Miao, Y., Li, Y., Qin, J., Guo, J., and Zha, W. National Science Review, 10(4), nwac285.

[238] Mechanochromic Response of Spiropyran‐Incorporated Liquid Crystalline Elastomer Network and the Mechanochromic Enhancement by Nano Zinc Oxide. Han, D., Wang, X., Liu, S., Zhang, Y., Li, C., Gao, Y., and Zhang, J. Advanced Materials Technologies, 8(17), 2300175.

[239] Mitigating Coffee Ring Effects for Efficient Upscaling of Flexible Organic Solar Cells. Tian, C., Zhang, J., Shen, Y., Zhang, H., Zhang, Z., Qiu, D., Zhang, L., and Wei, Z. Solar RRL, 7(14), 2300349.

[240] Molecular Orientation‐Dependent Exciton Separation in Optimized Single‐Component Y6 Organic Solar Cells. Yan, Y., Zhao, S., Zhang, Y., Wang, T., Shi, Y., Qiu, D., Zhang, J., Zhu, L., Wang, M., and Qiao, J. Solar RRL, 7(18), 2300342.

[241] Optimization of Charge Management and Energy Loss in All‐Small‐Molecule Organic Solar Cells. Zhang, L., Deng, D., Lu, K., and Wei, Z. Advanced Materials, 2302915.

[242] Optimized Crystal Framework by Asymmetric Core Isomerization in Selenium‐Substituted Acceptor for Efficient Binary Organic Solar Cells. Yang, C., An, Q., Jiang, M., Ma, X., Mahmood, A., Zhang, H., Zhao, X., Zhi, H. F., Jee, M. H., and Woo, H. Y. Angewandte Chemie, 135(49), e202313016.

[243] Recent Progress on Organic Near‐Infrared Photodetectors: Mechanism, Devices, and Applications. Wang, Q., Zhang, Y., and Wei, Z. Chinese Journal of Chemistry, 41(8), 958-978.

[244] Selective halogenation of central and end-units of nonfullerene acceptors enables enhanced molecular packing and photovoltaic performance. Xie, M., Shi, Y., Zhu, L., Zhang, J., Cheng, Q., Zhang, H., Yan, Y., Zhu, M., Zhou, H., and Lu, K. Energy & Environmental Science, 16(8), 3543-3551.

[245] Selenium Substitution in Bithiophene Imide Polymer Semiconductors Enables High‐Performance n‐Type Organic Thermoelectric. Li, J., Liu, M., Yang, K., Wang, Y., Wang, J., Chen, Z., Feng, K., Wang, D., Zhang, J., and Li, Y. Advanced Functional Materials, 33(23), 2213911.

[246] Single-bond-linked oligomeric donors for high performance organic solar cells. Lv, M., Tang, Y., Qiu, D., Zou, W., Zhou, R., Liu, L., Huang, Z., Zhang, J., Lu, K., and Wei, Z. Chinese Chemical Letters, 34(2), 107321.

[247] Slot-die coated large-area flexible all-polymer solar cells by non-halogenated solvent. Shen, Y.-F., Zhang, J., Tian, C., Qiu, D., and Wei, Z. Nano Research, 16(12), 13008-13013.

[248] Small Energetic Disorder Enables Ultralow Energy Losses in Non‐Fullerene Organic Solar Cells. Shi, Y., Zhu, L., Yan, Y., Xie, M., Liang, G., Qiao, J., Zhang, J., Hao, X., Lu, K., and Wei, Z. Advanced Energy Materials, 13(19), 2300458.

[249] Small Molecule Donors Design Rules for Non‐Halogen Solvent Fabricated Organic Solar Cells. Ma, X., Wang, C., Deng, D., Zhang, H., Zhang, L., Zhang, J., Yang, Y., and Wei, Z. Small, 2309042.

[250] Stereoisomeric Non‐Fullerene Acceptors‐Based Organic Solar Cells. Liu, L., Yan, Y., Zhao, S., Wang, T., Zhang, W., Zhang, J., Hao, X., Zhang, Y., Zhang, X., and Wei, Z. Small, 20(3), 2305638.

[251] Strengthening the Hetero‐Molecular Interactions in Giant Dimeric Acceptors Enables Efficient Organic Solar Cells. Lv, M., Wang, Q., Zhang, J., Wang, Y., Zhang, Z. G., Wang, T., Zhang, H., Lu, K., Wei, Z., and Deng, D. Advanced Materials, 36(4), 2310046.

[252] Unique assembly of giant star-shaped trimer enables non-halogen solvent-fabricated, thermal stable, and efficient organic solar cells. Wang, C., Ma, X., Shen, Y.-f., Deng, D., Zhang, H., Wang, T., Zhang, J., Li, J., Wang, R., and Zhang, L. Joule, 7(10), 2386-2401.

2022

[197] Actuation performance of a liquid crystalline elastomer composite reinforced by eiderdown fibers. Zhao, N., Wang, X., Yao, L., Yan, H., Qin, B., Li, C., and Zhang, J. Soft Matter, 18(6), 1264-1274.

[198] Alignment of Organic Conjugated Molecules for High‐Performance Device Applications. Memon, W. A., Zhang, Y., Zhang, J., Yan, Y., Wang, Y., and Wei, Z. Macromolecular Rapid Communications, 43(14), 2100931.

[199] Aryl-substituted-indanone end-capped nonfullerene acceptors for organic solar cells with a low nonradiative loss. Xie, M., Shi, Y., Zhang, H., Pan, J., Zhang, J., Wei, Z., and Lu, K. Chemical Communications, 58(31), 4877-4880.

[200] Building supramolecular chirality in bulk heterojunctions enables amplified dissymmetry current for high-performing circularly polarized light detection. Liu, L., Yang, Y., Wang, Y., Adil, M. A., Zhao, Y., Zhang, J., Chen, K., Deng, D., Zhang, H., and Amin, K. ACS Materials Letters, 4(2), 401-409.

[201] Chiral non‐fullerene acceptor enriched bulk heterojunctions enable high‐performance near‐infrared circularly polarized light detection. Liu, L., Yang, Y., Zhu, L., Zhang, J., Chen, K., and Wei, Z. Small, 18(31), 2202941.

[202] Donor End‐Capped Alkyl Chain Length Dependent Non‐Radiative Energy Loss in All‐Small‐Molecule Organic Solar Cells. Zhang, L., Sun, R., Zhang, Z., Zhang, J., Zhu, Q., Ma, W., Min, J., Wei, Z., and Deng, D. Advanced Materials, 34(50), 2207020.

[203] Efficient charge generation and low open circuit voltage loss enable a PCE of 10.3% in small molecule donor and polymer acceptor organic solar cells. Li, Y., Deng, D., Sun, R., Wu, S., Zhang, L., Zhang, Z., Zhang, J., Min, J., Zhao, G., and Wei, Z. Journal of Materials Chemistry C, 10(7), 2639-2647.

[204] Electron-deficient TVT unit-based D–A polymer donor for high-efficiency thick-film OSCs. Zhang, L., Chang, Y., Zhu, X., Yang, C., Shi, Y., Zhang, J., Sun, X., Lu, K., and Wei, Z. Nanotechnology, 33(6), 065401.

[205] Hierarchical phase separation in all small-molecule organic solar cells. Iqbal, M. J., Zhang, J., and Wei, Z. Journal of Nanoparticle Research, 24(11), 225.

[206] High Miscibility Compatible with Ordered Molecular Packing Enables an Excellent Efficiency of 16.2% in All‐Small‐Molecule Organic Solar Cells. Zhang, L., Zhu, X., Deng, D., Wang, Z., Zhang, Z., Li, Y., Zhang, J., Lv, K., Liu, L., and Zhang, X. Advanced Materials, 34(5), 2106316.

[207] Investigation of charge transfer between donor and acceptor for small-molecule organic solar cells by scanning tunneling microscopy and ultrafast transient absorption spectroscopy. Xiao, Y., Cheng, L., Sui, X., Wang, Q., Chen, J., Deng, D., Zhang, J., Peng, X., Li, X., and Xiao, X. Nano Research, 15(9), 8019-8027.

[208] Layer‐by‐layer processed pm6: Y6‐based stable ternary polymer solar cells with improved efficiency over 18% by incorporating an asymmetric thieno [3, 2‐b] indole‐based acceptor. Chen, J., Cao, J., Liu, L., Xie, L., Zhou, H., Zhang, J., Zhang, K., Xiao, M., and Huang, F. Advanced Functional Materials, 32(25), 2200629.

[209] Low nonradiative energy losses within 0.2 eV in efficient non-fullerene all-small-molecule organic solar cells. Huang, Z., Shi, Y., Chang, Y., Yang, C., Lv, M., Shen, Y., Liu, Y., Zhang, J., Lu, K., and Wei, Z. Journal of Materials Chemistry C, 10(7), 2800-2806.

[210] “N‐π‐N” Type Oligomeric Acceptor Achieves an OPV Efficiency of 18.19% with Low Energy Loss and Excellent Stability. Zhang, L., Zhang, Z., Deng, D., Zhou, H., Zhang, J., and Wei, Z. Advanced Science, 9(23), 2202513.

[211] Optical wavelength selective actuation of dye doped liquid crystalline elastomers by quasi-daylight. Zhang, X., Yao, L., Yan, H., Zhang, Y., Han, D., He, Y., Li, C., and Zhang, J. Soft Matter, 18(48), 9181-9196.

[212] Organic solar cells based on small molecule donor and polymer acceptor. Xu, W., Chang, Y., Zhu, X., Wei, Z., Zhang, X., Sun, X., Lu, K., and Wei, Z. Chinese Chemical Letters, 33(1), 123-132.

[213] Polymerized Small‐Molecule Acceptor as an Interface Modulator to Increase the Performance of All‐Small‐Molecule Solar Cells. Zhang, Z., Deng, D., Li, Y., Ding, J., Wu, Q., Zhang, L., Zhang, G., Iqbal, M. J., Wang, R., and Zhang, J. Advanced Energy Materials, 12(3), 2102394.

[214] Precise control of crystal orientation of conjugated molecule enables anisotropic charge transport properties. Memon, W. A., Zhou, R., Zhang, Y., Wang, Y., Liu, L., Yang, C., Zhang, J., Liaqat, A., Xie, L., and Wei, Z. Advanced Functional Materials, 32(9), 2110080.

[215] Pushing the Efficiency of High Open‐Circuit Voltage Binary Organic Solar Cells by Vertical Morphology Tuning. Cai, G., Chen, Z., Xia, X., Li, Y., Wang, J., Liu, H., Sun, P., Li, C., Ma, R., and Zhou, Y. Advanced Science, 9(14), 2200578.

[216] PVDF-HFP layer with high porosity and polarity for high-performance lithium metal anodes in both ether and carbonate electrolytes. Lu, R., Shokrieh, A., Li, C., Zhang, B., Amin, K., Mao, L., and Wei, Z. Nano Energy, 95, 107009.

[217] Regulating phase separation and molecular stacking by introducing siloxane to small-molecule donors enables high efficiency all-small-molecule organic solar cells. Chang, Y., Zhu, X., Shi, Y., Liu, Y., Meng, K., Li, Y., Xue, J., Zhu, L., Zhang, J., and Zhou, H. Energy & Environmental Science, 15(7), 2937-2947.

[218] Revealing aggregation of non-fullerene acceptors in intermixed phase by ultraviolet-visible absorption spectroscopy. Fang, J., Wang, Z., Chen, Y., Zhang, Q., Zhang, J., Zhu, L., Zhang, M., Cui, Z., Wei, Z., and Ade, H. Cell Reports Physical Science, 3(7).

[219] Robust Anion‐Shielding Metal‐Organic Frameworks Based Composite Interlayers To Achieve Uniform Li Deposition for Stable Li‐Metal Anode. Li, C., Lu, R., Amin, K., Zhang, B., Liu, H., Zheng, W., Guo, J., Du, P., Mao, L., and Lu, X. ChemElectroChem, 9(3), e202101596.

[220] The role of entropy gains in the exciton separation in organic solar cells. Yan, Y., Zhang, Y., Memon, W. A., Wang, M., Zhang, X., and Wei, Z. Macromolecular Rapid Communications, 43(16), 2100903.

[221] Simultaneously decreasing the bandgap and Voc loss in efficient ternary organic solar cells. Yan, Y., Zhang, Y., Liu, Y., Shi, Y., Qiu, D., Deng, D., Zhang, J., Wang, B., Adil, M. A., and Amin, K. Advanced Energy Materials, 12(20), 2200129.

[222] Small reorganization energy acceptors enable low energy losses in non-fullerene organic solar cells. Shi, Y., Chang, Y., Lu, K., Chen, Z., Zhang, J., Yan, Y., Qiu, D., Liu, Y., Adil, M. A., and Ma, W. Nature Communications, 13(1), 3256.

[223] Thermo-crosslinking assisted preparation of thiol-acrylate main-chain liquid-crystalline elastomers. Yan, H., He, Y., Yao, L., Wang, X., Zhang, X., Zhang, Y., Han, D., Li, C., Sun, L., and Zhang, J. Journal of Polymer Research, 29(11), 450.

[224] Trifluoro alkyl side chains in the non-fullerene acceptors to optimize the phase miscibility and vertical distribution of organic solar cells. Zhang, T., Chen, H., Li, C., Lu, K., Zhang, L., Shokrieh, A., Zhang, J., Lu, G., Lei, S., and Wei, Z. Journal of Materials Chemistry A, 10(16), 8837-8845.

[225] Utilizing Ternary Strategy to Reduce the Influence of Polymer Batch‐to‐Batch Variation in Organic Solar Cells. Adil, M. A., Memon, W. A., Zhang, J., Iqbal, M. J., Yang, C., Wang, Y., Zou, W., and Wei, Z. Solar RRL, 6(6), 2101083.

2021

[173] 17% efficiency all-small-molecule organic solar cells enabled by nanoscale phase separation with a hierarchical branched structure. Qin, J., Chen, Z., Bi, P., Yang, Y., Zhang, J., Huang, Z., Wei, Z., An, C., Yao, H., and Hao, X. Energy & Environmental Science, 14(11), 5903-5910.

[174] 18.4% efficiency achieved by the cathode interface engineering in non-fullerene polymer solar cells. Qin, Y., Chang, Y., Zhu, X., Gu, X., Guo, L., Zhang, Y., Wang, Q., Zhang, J., Zhang, X., and Liu, X. Nano Today, 41, 101289.

[175] Combining chlorination and sulfuration strategies for high-performance all-small-molecule organic solar cells. Zhou, R., Yang, C., Zou, W., Adil, M. A., Li, H., Lv, M., Huang, Z., Lv, M., Zhang, J., and Lu, K. Journal of Energy Chemistry, 52, 228-233.

[176] Constructing high efficiency non-fullerene all-small-molecule ternary organic solar cells by employing structurally similar acceptors. Huang, Z., Zhou, R., Lv, M., Zhang, H., Yang, C., Shi, Y., Tang, Y., Zhang, J., Lu, K., and Wei, Z. Materials Chemistry Frontiers, 5(3), 1405-1409.

[177] Creating side transport pathways in organic solar cells by introducing delayed fluorescence molecules. Wang, Z., Wang, R., Mi, Y., Lu, K., Liu, Y., Yang, C., Zhang, J., Liu, X., Wang, Y., and Shuai, Z. Chemistry of Materials, 33(12), 4578-4585.

[178] Developing s-Tetrazine-Based Terpolymer for High-Performance Polymer Solar Cells by Tuning Side Chains. Xu, L., Tao, W., Guan, M., Yang, X., Huang, M., Chen, H., Zhang, J., Zhao, B., and Tan, S. ACS Applied Energy Materials, 4(10), 11624-11633.

[179] Dual-regulation of ions/electrons in a 3D Cu–Cu x O host to guide uniform lithium growth for high-performance lithium metal anodes. Lu, R., Zhang, B., Cheng, Y., Amin, K., Yang, C., Zhou, Q., Mao, L., and Wei, Z. Journal of Materials Chemistry A, 9(16), 10393-10403.

[180] An efficiency of 16.46% and a T 80 lifetime of over 4000 h for the PM6: Y6 inverted organic solar cells enabled by surface acid treatment of the zinc oxide electron transporting layer. Han, Y., Dong, H., Pan, W., Liu, B., Chen, X., Huang, R., Li, Z., Li, F., Luo, Q., and Zhang, J. ACS Applied Materials & Interfaces, 13(15), 17869-17881.

[181] In situ generated mixed ion/electron-conducting scaffold with uniform Li deposition for flexible Li metal anodes. Cheng, Y., Lu, R., Amin, K., Zhang, B., Zhou, Q., Li, C., Mao, L., Zhang, Z., Lu, X., and Wei, Z. ACS Applied Energy Materials, 4(6), 6106-6115.

[182] Influence of the terminal group on optoelectronic properties of fused-ring nonfullerene acceptors with ethylhexyl side chain. Zhang, Q., Adil, M. A., Wang, Z., Zhao, G., Wang, T., Jiang, R., Zhang, J., and Wang, Q. Dyes and Pigments, 194, 109635.

[183] Mixed Solvent as a Critical Factor in Optimizing Phase Separation of All Small Molecule Organic Solar Cells. Liu, Y., Zhang, J., Yan, Y., Yang, C., Pan, J., Zhang, X., and Wei, Z. ACS Applied Energy Materials, 4(10), 11769-11776.

[184] Optimizing polymer aggregation and blend morphology for boosting the photovoltaic performance of polymer solar cells via a random terpolymerization strategy. Zhang, T., An, C., Lv, Q., Qin, J., Cui, Y., Zheng, Z., Xu, B., Zhang, S., Zhang, J., and He, C. Journal of Energy Chemistry, 59, 30-37.

[185] Optimizing the charge carrier and light management of nonfullerene acceptors for efficient organic solar cells with small nonradiative energy losses. Shi, Y., Pan, J., Yu, J., Zhang, J., Gao, F., Lu, K., and Wei, Z. Solar RRL, 5(4), 2100008.

[186] Optimizing the energy levels and crystallinity of 2, 2′-bithiophene-3, 3′-dicarboximide-based polymer donors for high-performance non-fullerene organic solar cells. Tang, Y., Xie, L., Qiu, D., Yang, C., Liu, Y., Shi, Y., Huang, Z., Zhang, J., Hu, J., and Lu, K. Journal of Materials Chemistry C, 9(24), 7575-7582.

[187] Probing molecular orientation at bulk heterojunctions by polarization-selective transient absorption spectroscopy. Zhang, C., Zhang, Y., Wang, Z., Su, Y., Wei, Z., Hou, J., He, S., Wu, K., He, C., and Zhang, J. Science China Chemistry, 64(9), 1569-1576.

[188] Regioregular narrow bandgap copolymer with strong aggregation ability for high-performance semitransparent photovoltaics. Chang, Y., Zhu, X., Zhu, L., Wang, Y., Yang, C., Gu, X., Zhang, Y., Zhang, J., Lu, K., and Sun, X. Nano Energy, 86, 106098.

[189] Simultaneously Enhancing the J sc and V oc of Ternary Organic Solar Cells by Incorporating a Medium-Band-Gap Acceptor. Zhang, M., Zeng, M., Deng, X., Zhou, Z., Tan, X., Tan, S., Zhao, B., Zhang, J., and Zou, Y. ACS Applied Energy Materials, 4(4), 3480-3486.

[190] Small-molecule acceptors with long alkyl chains for high-performance as-cast nonfullerene organic solar cells. Lin, H., Adil, M. A., Zhang, Q., Zhang, J., and Wang, Q. Organic Electronics, 93, 106167.

[191] Small exciton binding energies enabling direct charge photogeneration towards low‐driving‐force organic solar cells. Zhu, L., Zhang, J., Guo, Y., Yang, C., Yi, Y., and Wei, Z. Angewandte Chemie, 133(28), 15476-15481.

[192] The substituents on the intermediate electron-deficient groups in small molecular acceptors result appropriate morphologies for organic solar cells. Shi, Y., Pan, J., Zhang, H., Yang, C., Zhang, Z., Deng, D., Zhang, J., Lu, K., and Wei, Z. Organic Electronics, 93, 106133.

[193] Sulfur Compensation: A Promising Strategy against Capacity Decay in Li–S Batteries. Zhang, B., Lu, R., Cheng, Y., Amin, K., Mao, L., and Wei, Z. ACS Applied Materials & Interfaces, 13(49), 58771-58780.

[194] Top and bottom electrode optimization enabled high-performance flexible and semi-transparent organic solar cells. Wang, Y., Wang, G., Xing, Y., Adil, M. A., Memon, W. A., Chang, Y., Liu, L., Yang, C., Zhang, M., and Li, D. Materials Chemistry Frontiers, 5(11), 4310-4316.

[195] Volatilizable solid additive‐assisted treatment enables organic solar cells with efficiency over 18.8% and fill factor exceeding 80%. Bao, S., Yang, H., Fan, H., Zhang, J., Wei, Z., Cui, C., and Li, Y. Advanced Materials, 33(48), 2105301.

[196] π-extended nonfullerene acceptors for efficient organic solar cells with a high open-circuit voltage of 0.94 V and a low energy loss of 0.49 eV. Pan, J., Shi, Y., Yu, J., Zhang, H., Liu, Y., Zhang, J., Gao, F., Yu, X., Lu, K., and Wei, Z. ACS applied materials & interfaces, 13(19), 22531-22539.

2020

[149] 15.3% efficiency all-small-molecule organic solar cells enabled by symmetric phenyl substitution. Qin, J., An, C., Zhang, J., Ma, K., Yang, Y., Zhang, T., Li, S., Xian, K., Cui, Y., and Tang, Y. Sci. China Mater, 63(7), 1142-1150.

[150] Effect of Side-Chain Variation on Single-Crystalline Structures for Revealing the Structure–Property Relationships of Organic Solar Cells. Yang, C., Yuan, L., Zhou, R., Wang, Z., Zhang, J., Zhang, Y., Lu, K., and Wei, Z. Organic Materials, 2(01), 026-032.

[151] Efficient As‐Cast Polymer Solar Cells with High and Stabilized Fill Factor. Fang, J., Liu, Q., Zhang, J., Ye, L., Wu, J., Wei, Z., Guo, X., Zhang, M., and Li, Y. Solar RRL, 4(10), 2000275.

[152] Enhancing the photovoltaic performance of heteroheptacene-based nonfullerene acceptors through the synergistic effect of side-chain engineering and fluorination. Cai, D., Zhang, J., Wang, J.-Y., Ma, Y., Wan, S., Wang, P., Wei, Z., and Zheng, Q. Journal of Materials Chemistry A, 8(46), 24543-24552.

[153] High‐Efficient Charge Generation in Single‐Donor‐Component‐Based p‐i‐n Structure Organic Solar Cells. Zhang, Y., Deng, D., Wu, Q., Mi, Y., Yang, C., Zhang, X., Yang, Y., Zou, W., Zhang, J., and Zhu, L. Solar RRL, 4(4), 1900580.

[154] Ideal alloys of two donor isomers with non-covalently conformational locking for ternary organic solar cells. Deng, D., Zhang, H., Wu, Q., Adil, M. A., Yang, C., Zhang, J., and Wei, Z. Journal of Materials Chemistry C, 8(22), 7519-7526.

[155] Improved photovoltaic properties of PM6-based terpolymer donors containing benzothiadiazole with a siloxane-terminated side chain. Xu, W., Zhang, M., Xiao, J., Zeng, M., Ye, L., Weng, C., Zhao, B., Zhang, J., and Tan, S. Polymer Chemistry, 11(38), 6178-6186.

[156] Long-term stable and highly efficient perovskite solar cells with a formamidinium chloride (FACl) additive. You, S., Xi, X., Zhang, X., Wang, H., Gao, P., Ma, X., Bi, S., Zhang, J., Zhou, H., and Wei, Z. Journal of Materials Chemistry A, 8(34), 17756-17764.

[157] Modulation of donor alkyl terminal chains with the shifting branching point leads to the optimized morphology and efficient all-small-molecule organic solar cells. Wu, Q., Deng, D., Zhou, R., Zhang, J., Zou, W., Liu, L., Wu, S., Lu, K., and Wei, Z. ACS applied materials & interfaces, 12(22), 25100-25107.

[158] Moving Alkyl‐Chain Branching Point Induced a Hierarchical Morphology for Efficient All‐Small‐Molecule Organic Solar Cells. Zhou, R., Jiang, Z., Shi, Y., Wu, Q., Yang, C., Zhang, J., Lu, K., and Wei, Z. Advanced Functional Materials, 30(51), 2005426.

[159] Nitrogen‐doped nanoarray‐modified 3D hierarchical graphene as a cofunction host for high‐performance flexible Li‐S battery. Lu, R., Cheng, M., Mao, L., Zhang, M., Yuan, H., Amin, K., Yang, C., Cheng, Y., Meng, Y., and Wei, Z. EcoMat, 2(1), e12010.

[160] Orientationally engineered 2D/3D perovskite for high efficiency solar cells. Abbas, M. S., Hussain, S., Zhang, J., Wang, B., Yang, C., Wang, Z., Wei, Z., and Ahmad, R. Sustainable Energy & Fuels, 4(1), 324-330.

[161] The post-treatment effects on open circuit voltages and device performances in a high efficiency all-small-molecule organic solar cell. Zhang, Z., Wu, Q., Deng, D., Wu, S., Sun, R., Min, J., Zhang, J., and Wei, Z. Journal of Materials Chemistry C, 8(43), 15385-15392.

[162] A privileged ternary blend enabling non-fullerene organic photovoltaics with over 14% efficiency. Yan, J., Zhang, J., Feng, H., Ma, Y., Wan, X., Li, C., Wei, Z., and Chen, Y. Journal of Materials Chemistry C, 8(43), 15135-15141.

[163] Red-emissive poly (phenylene vinylene)-derivated semiconductors with well-balanced ambipolar electrical transporting properties. Zhang, Y., Ye, J., Liu, Z., Liu, Q., Guo, X., Dang, Y., Zhang, J., Wei, Z., Wang, Z., and Wang, Z. Journal of Materials Chemistry C, 8(31), 10868-10879.

[164] Regulating the phase separation of ternary organic solar cells via 3D architectured AIE molecules. Adil, M. A., Zhang, J., Wang, Y., Yu, J., Yang, C., Lu, G., and Wei, Z. Nano Energy, 68, 104271.

[165] Scalable Production of Wearable Solid‐State Li‐Ion Capacitors from N‐Doped Hierarchical Carbon. Xu, Y., Wang, K., Han, J., Liu, C., An, Y., Meng, Q., Li, C., Zhang, X., Sun, X., and Zhang, Y. Advanced Materials, 32(45), 2005531.

[166] Semitransparent flexible organic solar cells. Wang, Y., Chang, Y., Zhang, J., Lu, G., and Wei, Z. Chemical Research in Chinese Universities, 36(3), 343-350.

[167] Simultaneous performance and stability improvement of ternary polymer solar cells enabled by modulating the molecular packing of acceptors. Gu, H., Yan, L., Li, Z., Zhang, J., Luo, Q., Yang, Y., Liu, X., Wei, Z., and Ma, C.-Q. Solar RRL, 4(10), 2000374.

[168] Study of photovoltaic performances for asymmetrical and symmetrical chlorinated thiophene-bridge-based conjugated polymers. Ma, K., An, C., Zhang, T., Lv, Q., Zhang, S., Zhou, P., Zhang, J., and Hou, J. Journal of Materials Chemistry C, 8(7), 2301-2306.

[169] Surface controlled pseudo-capacitive reactions enabling ultra-fast charging and long-life organic lithium ion batteries. Amin, K., Zhang, J., Zhou, H.-Y., Lu, R., Zhang, M., Ashraf, N., YueLi, C., Mao, L., Faul, C. F., and Wei, Z. Sustainable Energy & Fuels, 4(8), 4179-4185.

[170] Synergistic optimization enables large‐area flexible organic solar cells to maintain over 98% PCE of the small‐area rigid devices. Wang, G., Zhang, J., Yang, C., Wang, Y., Xing, Y., Adil, M. A., Yang, Y., Tian, L., Su, M., and Shang, W. Advanced Materials, 32(49), 2005153.

[171] Ternary organic solar cells based on two non‐fullerene acceptors with complimentary absorption and balanced crystallinity. Xie, L., Yang, C., Zhou, R., Wang, Z., Zhang, J., Lu, K., and Wei, Z. Chinese Journal of Chemistry, 38(9), 935-940.

[172] Ultrasonics Sonochemistry Assisted Preparation of Polysiloxane Main‐Chain Liquid‐Crystalline Elastomers. Wang, X., Zhao, N., Qin, B., Xu, J., Yang, W., Li, C., Sun, L., and Zhang, J. Macromolecular Chemistry and Physics, 221(11), 2000071.

2019

[139] All-small-molecule organic solar cells with over 14% efficiency by optimizing hierarchical morphologies. Zhou, R., Jiang, Z., Yang, C., Yu, J., Feng, J., Adil, M. A., Deng, D., Zou, W., Zhang, J., and Lu, K. Nature communications, 10(1), 5393.

[140] A Bifunctional and Free‐Standing Organic Composite Film with High Flexibility and Good Tensile Strength for Tribological and Electrochemical Applications. Ahmad, A., Imani, A., Mao, L., Iqbal, R., Zhang, H., Ghazi, Z. A., Ahmad, R., Khan, A. A., Xie, L., and Chen, C. M. Advanced Materials Technologies, 4(10), 1900617.

[141] Cable‐Shaped Lithium–Sulfur Batteries Based on Nitrogen‐Doped Carbon/Carbon Nanotube Composite Yarns. Yuan, H., Zhang, M., Yang, C., Liu, L., Lu, R., Mao, L., and Wei, Z. Macromolecular Materials and Engineering, 304(8), 1900201.

[142] Chain Engineering of Benzodifuran‐Based Wide‐Bandgap Polymers for Efficient Non‐Fullerene Polymer Solar Cells. Zhu, R., Wang, Z., Gao, Y., Zheng, Z., Guo, F., Gao, S., Lu, K., Zhao, L., and Zhang, Y. Macromolecular Rapid Communications, 40(19), 1900227.

[143] Constructing High‐Performance All‐Small‐Molecule Ternary Solar Cells with the Same Third Component but Different Mechanisms for Fullerene and Non‐fullerene Systems. Chang, Y., Chang, Y., Zhu, X., Zhou, X., Yang, C., Zhang, J., Lu, K., Sun, X., and Wei, Z. Advanced Energy Materials, 9(16), 1900190.

[144] Fluorination-substitution effect on all-small-molecule organic solar cells. Wu, Q., Deng, D., Zhang, J., Zou, W., Yang, Y., Wang, Z., Li, H., Zhou, R., Lu, K., and Wei, Z. Science China Chemistry, 62, 837-844.

[145] Large‐area organic solar cells: material requirements, modular designs, and printing methods. Wang, G., Adil, M. A., Zhang, J., and Wei, Z. Advanced Materials, 31(45), 1805089.

[146] Liquid‐crystalline small molecules for nonfullerene solar cells with high fill factors and power conversion efficiencies. Li, H., Wu, Q., Zhou, R., Shi, Y., Yang, C., Zhang, Y., Zhang, J., Zou, W., Deng, D., and Lu, K. Advanced Energy Materials, 9(6), 1803175.

[147] Nanowire Array-Coated Flexible Substrate to Accommodate Lithium Plating for Stable Lithium-Metal Anodes and Flexible Lithium–Organic Batteries. Zhang, M., Lu, R., Yuan, H., Amin, K., Mao, L., Yan, W., and Wei, Z. ACS applied materials & interfaces, 11(23), 20873-20880.

[148] A sequential slot‐die coated ternary system enables efficient flexible organic solar cells. Zhao, Y., Wang, G., Wang, Y., Xiao, T., Adil, M. A., Lu, G., Zhang, J., and Wei, Z. Solar RRL, 3(3), 1800333.

A-   π-D-π-A small-molecule donors with different end alkyl chains obtain different morphologies in organic solar cells. Shi, Y., Yang, C., Li, H., Liu, L., Zhou, R., Zou, W., Wang, Z., Wu, Q., Deng, D., and Zhang, J. Chinese Chemical Letters, 30(4), 906-910.

2018

[118] Aromatic end-capped acceptor effects on molecular stacking and the photovoltaic performance of solution-processable small molecules. Deng, D., Yang, Y., Zou, W., Zhang, Y., Wang, Z., Wang, Z., Zhang, J., Lu, K., Ma, W., and Wei, Z. Journal of materials chemistry A, 6(44), 22077-22085.

[119] A carbon foam-supported high sulfur loading composite as a self-supported cathode for flexible lithium–sulfur batteries. Zhang, M., Amin, K., Cheng, M., Yuan, H., Mao, L., Yan, W., and Wei, Z. Nanoscale, 10(46), 21790-21797.

[120] A carbonyl compound‐based flexible cathode with superior rate performance and cyclic stability for flexible lithium‐ion batteries. Amin, K., Meng, Q., Ahmad, A., Cheng, M., Zhang, M., Mao, L., Lu, K., and Wei, Z. Advanced materials, 30(4), 1703868.

[121] Critical role of vertical phase separation in small-molecule organic solar cells. Fang, J., Deng, D., Wang, Z., Adil, M. A., Xiao, T., Wang, Y., Lu, G., Zhang, Y., Zhang, J., and Ma, W. ACS applied materials & interfaces, 10(15), 12913-12920.

[122] Flexible VOx Nanosphere@SWCNT Hybrid Films with Dual‐Confinement Function of Polysulfides for High‐Performance Lithium–Sulfur Batteries. Zhang, M., Yang, Y., Zhang, X., Cheng, M., Yuan, H., Amin, K., Ahmad, A., Mao, L., Yan, W., and Wei, Z. Advanced Materials Interfaces, 5(18), 1800766.

[123] Fluorination Induced Donor to Acceptor Transformation in A1–D–A2–D–A1-Type Photovoltaic Small Molecules. Zhou, R., Xia, B., Li, H., Wang, Z., Yang, Y., Zhang, J., Laursen, B. W., Lu, K., and Wei, Z. Frontiers in Chemistry, 6, 384.

[124] From alloy-like to cascade blended structure: Designing high-performance all-small-molecule ternary solar cells. Wang, Z., Zhu, X., Zhang, J., Lu, K., Fang, J., Zhang, Y., Wang, Z., Zhu, L., Ma, W., and Shuai, Z. Journal of the American Chemical Society, 140(4), 1549-1556.

[125] A hierarchical porous N-doped carbon electrode with superior rate performance and cycling stability for flexible supercapacitors. Cheng, M., Meng, Y., Meng, Q., Mao, L., Zhang, M., Amin, K., Ahmad, A., Wu, S., and Wei, Z. Materials Chemistry Frontiers, 2(5), 986-992.

[126] Improve the performance of the all‐small‐molecule nonfullerene organic solar cells through enhancing the crystallinity of acceptors. Li, H., Zhao, Y., Fang, J., Zhu, X., Xia, B., Lu, K., Wang, Z., Zhang, J., Guo, X., and Wei, Z. Advanced Energy Materials, 8(11), 1702377.

[127] Macroscopic helical chirality and self-motion of hierarchical self-assemblies induced by enantiomeric small molecules. Yang, Y., Liang, J., Pan, F., Wang, Z., Zhang, J., Amin, K., Fang, J., Zou, W., Chen, Y., and Shi, X. Nature communications, 9(1), 3808.

[128] Modulating molecular orientation enables efficient nonfullerene small-molecule organic solar cells. Yang, L., Zhang, S., He, C., Zhang, J., Yang, Y., Zhu, J., Cui, Y., Zhao, W., Zhang, H., and Zhang, Y. Chemistry of Materials, 30(6), 2129-2134.

[129] Modulation of the Molecular Orientation at the Bulk Heterojunction Interface via Tuning the Small Molecular Donor–Nonfullerene Acceptor Interactions. Adil, M. A., Zhang, J., Deng, D., Wang, Z., Yang, Y., Wu, Q., and Wei, Z. ACS applied materials & interfaces, 10(37), 31526-31534.

[130] Multifunctional Diketopyrrolopyrrole‐Based Conjugated Polymers with Perylene Bisimide Side Chains. Li, C., Yu, C., Lai, W., Liang, S., Jiang, X., Feng, G., Zhang, J., Xu, Y., and Li, W. Macromolecular Rapid Communications, 39(14), 1700611.

[131] Naphtho [1, 2‐b: 5, 6‐b′] dithiophene‐Based Conjugated Polymers for Fullerene‐Free Inverted Polymer Solar Cells. Jiang, Z., Li, H., Wang, Z., Zhang, J., Zhang, Y., Lu, K., and Wei, Z. Macromolecular Rapid Communications, 39(14), 1700872.

[132] A novel small molecule based on naphtho [1, 2-b: 5, 6-b′] dithiophene benefits both fullerene and non-fullerene solar cells. Li, H., Fang, J., Zhang, J., Zhou, R., Wu, Q., Deng, D., Adil, M. A., Lu, K., Guo, X., and Wei, Z. Materials Chemistry Frontiers, 2(1), 143-148.

[133] Reducing the actuation threshold by incorporating a nonliquid crystal chain into a liquid crystal elastomer. Niu, H., Wang, Y., Wang, J., Yang, W., Dong, Y., Bi, M., Zhang, J., Xu, J., Bi, S., and Wang, B. RSC advances, 8(9), 4857-4866.

[134] Self‐assembled 3D helical hollow superstructures with enhanced microwave absorption properties. Yang, Y., Zhang, J., Zou, W., Wu, S., Wu, F., Xie, A., and Wei, Z. Macromolecular Rapid Communications, 39(3), 1700591.

[135] A Simple but Efficient Small Molecule with a High Open Circuit Voltage of 1.07 V in Solution‐Processable Organic Solar Cells. Deng, D., Zhang, Y., Wang, Z., Wu, Q., Ma, W., Lu, K., and Wei, Z. Asian Journal of Organic Chemistry, 7(3), 558-562.

[136] Small bandgap porphyrin-based polymer acceptors for non-fullerene organic solar cells. Zhou, S., Li, C., Ma, J., Guo, Y., Zhang, J., Wu, Y., and Li, W. Journal of Materials Chemistry C, 6(4), 717-721.

[137] Two-dimensional benzo [1, 2-b: 4, 5-b′] difuran-based wide bandgap conjugated polymers for efficient fullerene-free polymer solar cells. Gao, Y., Wang, Z., Zhang, J., Zhang, H., Lu, K., Guo, F., Yang, Y., Zhao, L., Wei, Z., and Zhang, Y. Journal of Materials Chemistry A, 6(9), 4023-4031.

[138] Wide-bandgap conjugated polymers based on alkylthiofuran-substituted benzo [1, 2-b: 4, 5-b′] difuran for efficient fullerene-free polymer solar cells. Gao, Y., Wang, Z., Zhang, J., Zhang, H., Lu, K., Guo, F., Wei, Z., Yang, Y., Zhao, L., and Zhang, Y. Macromolecules, 51(7), 2498-2505.

2017

[106] Combining energy transfer and optimized morphology for highly efficient ternary polymer solar cells. Zhao, F., Li, Y., Wang, Z., Yang, Y., Wang, Z., He, G., Zhang, J., Jiang, L., Wang, T., and Wei, Z. Advanced Energy Materials, 7(13), 1602552.

[107] The effect of tuning chemical structure on the open‐circuit voltage and photovoltaic performance of narrow band‐gap polymers. Li, H., Zhao, Y., Zhu, X., Xia, B., Lu, K., Yuan, L., Zhang, J., Guo, X., Yan, W., and Wei, Z. Journal of Polymer Science Part A: Polymer Chemistry, 55(4), 699-706.

[108] Enhancing performance of large‐area organic solar cells with thick film via ternary strategy. Zhang, J., Zhao, Y., Fang, J., Yuan, L., Xia, B., Wang, G., Wang, Z., Zhang, Y., Ma, W., and Yan, W. Small, 13(21), 1700388.

[109] Enhancing the photovoltaic performance via vertical phase distribution optimization in small molecule: PC71BM blends. Zhang, Y., Deng, D., Wang, Z., Wang, Y., Zhang, J., Fang, J., Yang, Y., Lu, G., Ma, W., and Wei, Z. Advanced Energy Materials, 7(22), 1701548.

[110] Evolution of morphology and open-circuit voltage in alloy-energy transfer coexisting ternary organic solar cells. Xia, B., Yuan, L., Zhang, J., Wang, Z., Fang, J., Zhao, Y., Deng, D., Ma, W., Lu, K., and Wei, Z. Journal of materials chemistry A, 5(20), 9859-9866.

[111] A hierarchically porous hypercrosslinked and novel quinone based stable organic polymer electrode for lithium-ion batteries. Ahmad, A., Meng, Q., Melhi, S., Mao, L., Zhang, M., Han, B.-H., Lu, K., and Wei, Z. Electrochimica Acta, 255, 145-152.

[112] High open-circuit voltage ternary organic solar cells based on ICBA as acceptor and absorption-complementary donors. Fang, J., Deng, D., Zhang, J., Zhang, Y., Lu, K., and Wei, Z. Materials Chemistry Frontiers, 1(6), 1223-1228.

[113] Investigation of conjugated polymers based on naphtho [2, 3-c] thiophene-4, 9-dione in fullerene-based and fullerene-free polymer solar cells. Yang, B., Zhang, S., Chen, Y., Cui, Y., Liu, D., Yao, H., Zhang, J., Wei, Z., and Hou, J. Macromolecules, 50(4), 1453-1462.

[114] Metal–organic framework-derived metal oxide embedded in nitrogen-doped graphene network for high-performance lithium-ion batteries. Sui, Z.-Y., Zhang, P.-Y., Xu, M.-Y., Liu, Y.-W., Wei, Z.-X., and Han, B.-H. ACS applied materials & interfaces, 9(49), 43171-43178.

[115] Poly (3, 4-ethylenedioxythiophene)-coated sulfur for flexible and binder-free cathodes of lithium–sulfur batteries. Zhang, M., Meng, Q., Ahmad, A., Mao, L., Yan, W., and Wei, Z. Journal of materials chemistry A, 5(33), 17647-17652.

[116] Toward over 15% power conversion efficiency for organic solar cells: current status and perspectives. Zhang, J., Zhu, L., and Wei, Z. Small Methods, 1(12), 1700258.

[117] Versatile asymmetric thiophene/benzothiophene flanked diketopyrrolopyrrole polymers with ambipolar properties for OFETs and OSCs. Jiang, Z., Ni, Z., Wang, H., Wang, Z., Zhang, J., Qiu, G., Fang, J., Zhang, Y., Dong, H., and Lu, K. Polymer Chemistry, 8(36), 5603-5610.

2016

[96] Acceptor End-Capped Oligomeric Conjugated Molecules with Broadened Absorption and Enhanced Extinction Coefficients for High-Efficiency Organic Solar Cells. Yuan, L., Lu, K., Xia, B., Zhang, J., Wang, Z., Deng, D., Fang, J., Zhu, L., and Wei, Z. Advanced Materials (Deerfield Beach, Fla.), 28(28), 5980-5985.

[97] A conformational locking strategy in linked-acceptor type polymers for organic solar cells. Xia, B., Lu, K., Yuan, L., Zhang, J., Zhu, L., Zhu, X., Deng, D., Li, H., and Wei, Z. Polymer Chemistry, 7(6), 1323-1329.

[98] Dialkoxyphenyldithiophene-based small molecules with enhanced absorption for solution processed organic solar cells. Zhao, J., Xia, B., Lu, K., Deng, D., Yuan, L., Zhang, J., Zhu, L., Zhu, X., Li, H., and Wei, Z. RSC advances, 6(65), 60595-60601.

[99] Fluorination-enabled optimal morphology leads to over 11% efficiency for inverted small-molecule organic solar cells. Deng, D., Zhang, Y., Zhang, J., Wang, Z., Zhu, L., Fang, J., Xia, B., Wang, Z., Lu, K., and Ma, W. Nature communications, 7(1), 13740.

[100]  Impact of the alkyl side chain position on the photovoltaic properties of solution-processable organic molecule donor materials. Zhang, J., Zhu, X., He, C., Bin, H., Xue, L., Wang, W., Yang, Y., Yuan, N., Ding, J., and Wei, Z. Journal of materials chemistry A, 4(30), 11747-11753.

[101] Naphtho [1, 2-b: 5, 6-b′] dithiophene-based small molecules for thick-film organic solar cells with high fill factors. Zhu, X., Xia, B., Lu, K., Li, H., Zhou, R., Zhang, J., Zhang, Y., Shuai, Z., and Wei, Z. Chemistry of Materials, 28(3), 943-950.

[102] Optimized “Alloy‐Parallel” Morphology of Ternary Organic Solar Cells. Wang, Z., Zhang, Y., Zhang, J., Wei, Z., and Ma, W. Advanced Energy Materials, 6(9), 1502456.

[103] Perfluoroalkyl-substituted conjugated polymers as electron acceptors for all-polymer solar cells: the effect of diiodoperfluoroalkane additives. Zhang, A., Wang, Q., Bovee, R. A., Li, C., Zhang, J., Zhou, Y., Wei, Z., Li, Y., Janssen, R. A., and Wang, Z. Journal of materials chemistry A, 4(20), 7736-7745.

[104] A polyimide derivative containing different carbonyl groups for flexible lithium ion batteries. Wu, H., Yang, Q., Meng, Q., Ahmad, A., Zhang, M., Zhu, L., Liu, Y., and Wei, Z. Journal of materials chemistry A, 4(6), 2115-2121.

[105] Self‐Doped and Crown‐Ether Functionalized Fullerene as Cathode Buffer Layer for Highly‐Efficient Inverted Polymer Solar Cells. Zhao, F., Wang, Z., Zhang, J., Zhu, X., Zhang, Y., Fang, J., Deng, D., Wei, Z., Li, Y., and Jiang, L. Advanced Energy Materials, 6(9).

2015

[95]Understanding effects of two different acceptors in one small molecule for solution processable organic solar cells, Y.F. Zhao, L. Yuan, J.Q. Zhang, L.Y. Zhu, K. Lu, W. Yan and Z.X. Wei, RSC Adv, 2015. (PDF)

[94]Enhancing the performance of polymer solar cells using CuPc nanocrystals as additives, Y.J. Zhang and Z.X. Wei,Nanotech, 2015. (PDF)

[93]Synergistic Effect of Polymer and Small Molecules for High-Performance Ternary Organic Solar Cells, Y.J. Zhang, D. Deng, K. Lu, J.Q. Zhang, B.Z. Xia, Y.F. Zhao, J. Fang and Z.X. Wei, Adv Mater, 2015. (PDF)

[92]Conjugated Polymer-Small Molecule Alloy Leads to High Efficient Ternary Organic Solar Cells, J.Q. Zhang, Y.J. Zhang, J. Fang, K. Lu, Z. Wang, W. Ma and Z.X. Wei, JACS, 2015. (PDF)

[91]Oligomeric Donor Material for High-Efficiency Organic Solar Cells: Breaking Down a Polymer, L. Yuan, Y.F. Zhao, J.Q. Zhang, Y.J. Zhang, L.Y. Zhu, K. Lu, W. Yan and Z.X. Wei, Adv Mater, 2015. (PDF)

[90]Poly(3,4-dinitrothiophene)/SWCNT composite as a low overpotential hydrogen evolution metal-free catalyst, K. Xie, H.P. Wu, Y.N. Meng, K. Lu, Z.X. Wei and Z. Zhang, J Mater Chem A, 2015. (PDF)

[89]Nitrogen-Doped Graphene Aerogels as Efficient Supercapacitor Electrodes and Gas Adsorbents, Z.Y. Sui, Y.N. Meng, P.W. Xiao, Z.Q. Zhao, Z.X. Wei and B.H. Han, Acs Appl Mater Inter, 2015. (PDF)

[88]Synergistic effect of a r-GO/PANI nanocomposite electrode based air working ionic actuator with a large actuation stroke and long-term durability, Q. Liu, L. Liu, K. Xie, Y.N. Meng, H.P. Wu, G.R. Wang, Z. Dai, Z.X. Wei and Z. Zhang, J Mater Chem A, 2015. (PDF)

[87]Modulating the Helicity of Sugar-Substituted Perylene Diimide Self-assemblies by Solvent Polarilities, Q. Guo, J. Wang, L.Y. Zhu and Z.X. Wei, Chinese J Chem, 2015. (PDF)

[86]Effects of end-capped acceptors subject to subtle structural changes on solution-processable small molecules for organic solar cells, D. Deng, Y.J. Zhang, L.Y. Zhu, J.Q. Zhang, K. Lu and Z.X. Wei, Phys Chem Chem Phys, 2015. (PDF)

2014 

[75]    Biomimetic Superhelical Conducting Microfibers with Homochirality for Enantioselective Sensing, W. J. Zou, Y. Yan, J. Fang, Y. Yang, J. Liang, K. Deng*, J. L. Yao*, Z. X. Wei*, J. Am. Chem. Soc., 2014, 136, 578.(PDF)   

[74]    Flexible and Binder-Free Organic Cathode for High-Performance Lithium-Ion Batteries, H. P. Wu, S. A. Shevlin, Q. H. Meng, W. Guo, Y. N. Meng, K. Lv*, Z. X. Wei*, Z. X. Guo*, Adv. Mater., 2014.(PDF) 

[72]    Conducting Polymer Nanowire Arrays for High Performance Supercapacitors, K. Wang, H. P. Wu, Y. N. Meng, Z. X. Wei*, Small, 2014, 10, 14.(PDF) 

[71]    Gamma-Irradiated Carbon Nanotube Yarn As Substrate for High-Performance Fiber Supercapacitors, F. H. Su, M. H. Miao*, H. T. Niu, Z. X. Wei, ACS Appl. Mater. Inter., 2014, 6, 2552.(PDF)   

[70]    High-Performance All-Carbon Yarn Micro-Supercapacitor for an Integrated Energy System, Q. H. Meng, H. P. Wu, Y. N. Meng, K. Xie, Z. X. Wei*, Z. X. Guo, Adv. Mater., 2014.(PDF) 

[69]    Thread-like Supercapacitors Based on One-Step Spun Nanocomposite Yarns, Q. H. Meng, K. Wang, W. Guo, J. Fang, Z. X. Wei*, X. L. She*, Small, 2014, n/a.(PDF) 

[68]    Nanoscale structural and electronic evolution for increased efficiency in polymer solar cells monitored by electric scanning probe microscopy, D. H. Li, H. Yan, C. Li, Y. L. Yang*, Z. X. Wei*, C. Wang*, Chin. Sci. Bull., 2014, 59, 360.(PDF) 

2013

[67]    Graphene-molybdenum oxynitride porous material with improved cyclic stability and rate capability for rechargeable lithium ion batteries, D. Zhou, H. P. Wu, Z. X. Wei*, B. H. Han*, Phys. Chem. Chem. Phys., 2013, 15, 16898.(PDF)  

[66]    Integrated Energy-Harvesting System by Combining the Advantages of Polymer Solar Cells and Thermoelectric Devices, Y. J. Zhang, J. Fang, C. He, H. Yan, Z. X. Wei*, Y. F. Li, J. Phys. Chem. C, 2013, 117, 24685.(PDF) 

[65]  Supramolecular Helices: Chirality Transfer from Conjugated Molecules to Structures, Y. Yang, Y. J. Zhang, Z. X. Wei*, Adv. Mater., 2013, 25, 6039.(PDF) 

[64]  A material combination principle for highly efficient polymer solar cells investigated by mesoscopic phase heterogeneity, H. Yan, D. H. Li, C. He, Z. X. Wei*, Y. L. Yang*, Y. F. Li, Nanoscale, 2013, 5, 11649.(PDF) 

[63]  An organic cathode material based on a polyimide/CNT nanocomposite for lithium ion batteries, H. P. Wu, K. Wang, Y. N. Meng, K. Lu, Z. X. Wei*, J. Mater. Chem. A,  2013, 1, 6366.(PDF) 

[62]  High-Performance Two-Ply Yarn Supercapacitors Based on Carbon Nanotubes and Polyaniline Nanowire Arrays, K. Wang, Q. H. Meng, Y. J. Zhang, Z. X. Wei*, M. H. Miao*, Adv. Mater. 2013, 25, 1494.(PDF) 

[61]  Hierarchical Porous Graphene/Polyaniline Composite Film with Superior Rate Performance for Flexible Supercapacitors, Y. N. Meng, K. Wang, Y. J. Zhang*, Z. X. Wei*, Adv. Mater., 2013, 25, 6985.(PDF) 

[60]  A facile strategy to enhance the fill factor of ternary blend solar cells by increasing charge carrier mobility, K. Lu, J. Fang, X. W. Zhu, H. Yan, D. H. Li, C. A. Di, Y. L. Yang, Z. X. Wei*, New J. Chem., 2013, 37, 1728.(PDF) 

[59]  A facile strategy to enhance absorption coefficient and photovoltaic performance of two-dimensional benzo 1,2-b:4,5-b ' dithiophene and thieno 3,4-c pyrrole-4,6-dione polymers via subtle chemical structure variations, K. Lu, J. Fang, H. Yan, X. W. Zhu, Y. P. Yi*, Z. X. Wei*, Organic Electronics, 2013, 14, 2652.(PDF) 

[58] Tuning PANI nanostructure by driving force for diverse capacitance performance, C. Li, L. Yang*, Y. N. Meng, X. J. Hu, Z. X. Wei, P. Chen, S. Y. Zhou*, Rsc Advances, 2013, 3, 21315.(PDF) 

[57]  Flexible high performance wet-spun graphene fiber supercapacitors, T. Q. Huang, B. N. Zheng, L. Kou, K. Gopalsamy, Z. Xu, C. Gao*, Y. N. Meng, Z. X. Wei*, Rsc Advances, 2013, 3, 23957.(PDF) 

[56]  Graphene oxide-based benzimidazole-crosslinked networks for high-performance supercapacitors, Y. Cui, Q. Y. Cheng, H. P. Wu, Z. X. Wei*, B. H. Han*, Nanoscale, 2013, 5, 8367.(PDF) 

[55]  Poly(ionic liquid)-derived nitrogen-doped hollow carbon spheres: synthesis and loading with Fe₂O₃ for high-performance lithium ion batteries, J. Balach, H. P. Wu, F. Polzer, H. Kirmse, Q. Zhao, Z. X. Wei*, J. Y. Yuan*, Rsc Advances, 2013, 3, 7979.(PDF) 

2012

[54]  Self-assembly of two-dimensional nanostructures of linear regioregular poly (3-hexylthiophene), Z. Yu, H. Yan, K. Lu, Y. J. Zhang, Z. X. Wei*, Rsc Advances, 2012, 2, 338.(PDF) 

[53]  Self-assembly of conjugated polymers for anisotropic nanostructures, Z. Yu, K. Lu, Z. X. Wei*, Science China-Chemistry, 2012, 55, 2283.(PDF) 

[52]  Self-Assembly of Well-Defined Poly(3-hexylthiophene) Nanostructures toward the Structure-Property Relationship Determination of Polymer Solar Cells, Z. Yu, J. Fang, H. Yan, Y. J. Zhang, K. Lu*, Z. X. Wei*, J. Phys. Chem. C, 2012, 116, 23858.(PDF) 

[51]  Helical heterojunctions originating from helical inversion of conducting polymer nanofibers, Y. Yan, J. Fang, J. Liang, Y. J. Zhang, Z. X. Wei*, Chemical Communications 2012, 48, 2843.(PDF) 

[50] Evolution of polymer photovoltaic performances from subtle chemical structure variations, H. Yan, D. H. Li, K. Lu*, X. W. Zhu, Y. J. Zhang, Y. L. Yang*, Z. X. Wei*, Phys. Chem. Chem. Phys. 2012, 14, 15127.(PDF) 

[49]  Bridging mesoscopic blend structure and property to macroscopic device performance via in situ optoelectronic characterization, H. Yan, D. H. Li, C. Li, K. Lu, Y. J. Zhang, Z. X. Wei*, Y. L. Yang*, C. Wang, J. Mater. Chem. 2012, 22, 4349.(PDF) 

[48]  Integrated energy storage and electrochromic function in one flexible device: an energy storage smart window, K. Wang, H. P. Wu, Y. N. Meng, Y. J. Zhang, Z. X. Wei*, Energy & Environmental Science 2012, 5, 8384.(PDF) 

[47] Block-like electroactive oligo(aniline)s: anisotropic structures with anisotropic function, Z. C. Shao, Z. Yu, J. C. Hu, S. Chandrasekaran, D. M. Lindsay, Z. X. Wei*, C. F. J. Faul*, J. Mater. Chem. 2012, 22, 16230.(PDF) 

[46]  Improving the performance of polymer solar cells by altering polymer side chains and optimizing film morphologies, K. Lu, J. Fang, Z. Yu, H. Yan, X. W. Zhu, Y. J. Zhang, C. He*, Z. X. Wei*, Organic Electronics 2012, 13, 3234.(PDF) 

[45]  Self-assembly of chiral amphiphiles with pi-conjugated tectons, Y. W. Huang, Z. X. Wei*, Chin. Sci. Bull. 2012, 57, 4246.(PDF) 

[44] Self-Assembled Sugar-Substituted Perylene Diimide Nanostructures with Homochirality and High Gas Sensitivity, J. C. Hu, W. F. Kuang, K. Deng, W. J. Zou, Y. W. Huang*, Z. X. Wei*, C. F. J. Faul, Adv. Funct. Mater. 2012, 22, 4149.(PDF) 

2011

[43]  Patterned Growth of Polyaniline Nanowire Arrays on a Flexible Substrate for High-Performance Gas Sensing, W. J. Zou, B. G. Quan, K. Wang, L. Xia, J. L. Yao*, Z. X. Wei*, Small 2011, 7, 3287.(PDF) 

[42] Self-Assembled Single-Crystal Polyaniline Microplates and Their Anisotropic Electrical Transport Property, Y. Yan, J. Fang, Y. J. Zhang, H. L. Fan, Z. X. Wei*, Macromol. Rapid Commun. 2011, 32, 1640.(PDF) 

[41]  Self-Assembly of Graphenelike ZnO Superstructured Nanosheets and Their Application in Hybrid Photoconductors, H. Yan, Z. Yu, K. Lu, Y. J. Zhang, Z. X. Wei*, Small 2011, 7, 3472.(PDF) 

[40]  Self-assembling branched and hyperbranched nanostructures of poly (3-hexylthiophene) by a solution process, H. Yan, Y. Yan, Z. Yu, Z. X. Wei*, The Journal of Physical Chemistry C 2011, 115, 3257.(PDF) 

[39]  Patterned growth of vertically aligned polypyrrole nanowire arrays, L. Xia, B. G. Quan, Z. X. Wei*, Macromol. Rapid Commun. 2011, 32, 1998.(PDF) 

[38]  An All-Solid-State Flexible Micro-supercapacitor on a Chip, K. Wang, W. J. Zou, B. G. Quan, A. F. Yu, H. P. Wu, P. Jiang, Z. X. Wei*, Advanced Energy Materials 2011, 1, 1068.(PDF) 

[37]  Flexible supercapacitors based on cloth-supported electrodes of conducting polymer nanowire array/SWCNT composites, K. Wang, P. Zhao, X. M. Zhou, H. P. Wu, Z. X. Wei*, J. Mater. Chem. 2011, 21, 16373.(PDF) 

[36]  Reversible underwater switching between superoleophobicity and superoleophilicity on conducting polymer nanotube arrays, M. J. Liu, X. L. Liu, C. M. Ding, Z. X. Wei*, Y. Zhu, L. Jiang*, Soft Matter 2011, 7, 4163.(PDF) 

[35]  Modulating helicity through amphiphilicity-tuning supramolecular interactions for the controlled assembly of perylenes, Y. W. Huang, J. C. Hu, W. F. Kuang, Z. X. Wei*, C. F. Faul, Chemical Communications 2011, 47, 5554.(PDF) 

[34]  Ammonia sensory properties based on single-crystalline micro/nanostructures of perylenediimide derivatives: core-substituted effect, Y. W. Huang*, L. N. Fu, W. J. Zou, F. L. Zhang, Z. X. Wei*, The Journal of Physical Chemistry C 2011, 115, 10399.(PDF) 

2010

[33]  Hierarchical crystalline superstructures of conducting polymers with homohelicity, Y. Yan, Y. J. Zhang, W. P. Hu, Z. X. Wei*, Chemistry-A European Journal 2010, 16, 8626.(PDF) 

[32]  Hexagonal Superlattice of Chiral Conducting Polymers Self-Assembled by Mimicking β-Sheet Proteins with Anisotropic Electrical Transport, Y. Yan, R. Wang, X. H. Qiu, Z. X. Wei*, J. Am. Chem. Soc. 2010, 132, 12006.(PDF) 

[31]  Hierarchical nanocomposites of polyaniline nanowire arrays on graphene oxide sheets with synergistic effect for energy storage, J. J. Xu, K. Wang, S. Z. Zu, B. H. Han*, Z. X. Wei*, ACS Nano 2010, 4, 5019.(PDF) 

[30]  Conducting polymer nanostructures and their application in biosensors, L. Xia, Z. X. Wei*, M. X. Wan*, J. Colloid Interface Sci. 2010, 341, 1.(PDF) 

[29]  Conducting polyaniline nanowire arrays for high performance supercapacitors, K. Wang, J. Y. Huang, Z. X. Wei*, The Journal of Physical Chemistry C 2010, 114, 8062.(PDF) 

[28]  Electromagnetic synergetic actuators based on polypyrrole/Fe3O4 hybrid nanotube arrays, M. J. Liu, X. L. Liu, J. X. Wang, Z. X. Wei*, L. Jiang*, Nano Research 2010, 3, 670.(PDF) 

[27]  Conducting polymer nanowire arrays with enhanced electrochemical performance, J. Y. Huang, K. Wang, Z. X. Wei*, J. Mater. Chem. 2010, 20, 1117.(PDF) 

Before 2009

[26]  Tuning the supramolecular chirality of polyaniline by methyl substitution, Y. Yan, K. Deng, Z. Yu, Z. X. Wei*, Angew. Chem. 2009, 121, 2037.(PDF) 

[25]  Decorating polypyrrole nanotubes with Au nanoparticles by an in situ reduction process, J. J. Xu, J. C. Hu, B. G. Quan, Z. X. Wei*, Macromol. Rapid Commun. 2009, 30, 936.(PDF) 

[24]  Stepwise Self-Assembly of P3HT/CdSe Hybrid Nanowires with Enhanced Photoconductivity, J. J. Xu, J. C. Hu, X. F. Liu, X. H. Qiu, Z. X. Wei*, Macromol. Rapid Commun. 2009, 30, 1419.(PDF) 

[23] Bioinspired design of a superoleophobic and low adhesive water/solid interface, M. J. Liu, S. T. Wang, Z. X. Wei, Y. L. Song, L. Jiang*, Adv. Mater. 2009, 21, 665.(PDF) 

[22]  In situ electrochemical switching of wetting state of oil droplet on conducting polymer films, M. J. Liu, F. Q. Nie, Z. X. Wei*, Y. L. Song, L. Jiang*, Langmuir 2009, 26, 3993.(PDF) 

[21]  Helical supramolecular aggregates, mesoscopic organisation and nanofibers of a perylenebisimide-chiral surfactant complex via ionic self-assembly, Y. W. Huang, Y. Yan, B. M. Smarsly, Z. X. Wei*, C. F. Faul*, J. Mater. Chem. 2009, 19, 2356.(PDF) 

[20] Self-assembled organic functional nanotubes and nanorods and their sensory properties, Y. W. Huang, B. G. Quan, Z. X. Wei*, G. T. Liu, L. F. Sun, The Journal of Physical Chemistry C 2009, 113, 3929.(PDF) 

[19]  Aniline oligomers–architecture, function and new opportunities for nanostructured materials, Z. X. Wei, C. F. Faul*, Macromol. Rapid Commun. 2008, 29, 280.(PDF) 

[18]  Polymer multilayer microspheres loaded with semiconductor quantum dots, A. Petukhova, A. S. Paton, Z. X. Wei, I. Gourevich, S. V. Nair, H. E. Ruda, A. Shik, E. Kumacheva*, Adv. Funct. Mater. 2008, 18, 1961.(PDF) 

[17]  Polypyrrole nanofiber arrays synthesized by a biphasic electrochemical strategy, M. Li, Z. X. Wei*, L. Jiang*, J. Mater. Chem. 2008, 18, 2276.(PDF) 

[16] Molecular imprinted polypyrrole nanowires for chiral amino acid recognition, J. Y. Huang, Z. X. Wei*, J. C. Chen*, Sensors and Actuators B: Chemical 2008, 134, 573.(PDF) 

[15]  Conducting polypyrrole conical nanocontainers: formation mechanism and voltage switchable property, J. Y. Huang, B. G. Quan, M. J. Liu, Z. X. Wei*, L. Jiang, Macromol. Rapid Commun. 2008, 29, 1335.(PDF) 

[14]  Formation of Chiral Mesopores in Conducting Polymers by Chiral-Lipid-Ribbon Templating and “Seeding” Route, C. X. Fan, H. B. Qiu, J. F. Ruan, O. Terasaki, Y. Yan, Z. X. Wei, S. Che*, Adv. Funct. Mater. 2008, 18, 2699.(PDF) 

[13]  Monodispersed ZnSe colloidal microspheres: preparation, characterization, and their 2D arrays, H. Z. Zhong, Z. X. Wei, M. F. Ye, Y. Yan, Y. Zhou, Y. Ding, C. H. Yang, Y. F. Li*, Langmuir 2007, 23, 9008.(PDF) 

[12]  Helical polyaniline nanofibers induced by chiral dopants by a polymerization process, Y. Yan, Z. Yu, Y. W. Huang, W. X. Yuan, Z. X. Wei*, Adv. Mater. 2007, 19, 3353.(PDF) 

[11]  TEM imaging of polymer multilayer particles: advantages, limitations, and artifacts, Z. X. Wei, I. Gourevich, L. Field, N. Coombs, E. Kumacheva*, Macromolecules 2006, 39, 2441.(PDF) 

[10]  Polymer multilayer particles: A route to spherical dielectric resonators, I. Gourevich, L. M. Field, Z. X. Wei, C. Paquet, A. Petukhova, A. Alteheld, E. Kumacheva*, J. J. Saarinen, J. Sipe, Macromolecules 2006, 39, 1449.(PDF) 

[9]  Polyaniline nanotubes and their dendrites doped with different naphthalene sulfonic acids, Z. M. Zhang, Z. X. Wei, L. J. Zhang, M. X. Wan*, Acta Mater. 2005, 53, 1373.(PDF) 

[8]  Self-Assembly and Electrical Conductivity Transitions in Conjugated Oligoaniline-Surfactant Complexes, Z. X. Wei, T. Laitinen, B. Smarsly, O. Ikkala, C. F. Faul*, Angew. Chem. 2005, 117, 761.(PDF) 

[7]  Self-Assembling Sub-Micrometer-Sized Tube Junctions and Dendrites of Conducting Polymers, Z. X. Wei, L. J. Zhang, M. Yu, Y. S. Yang, M. X. Wan*, Adv. Mater. 2003, 15, 1382.(PDF) 

[6]  Polyaniline Nanotubes Doped with Sulfonated Carbon Nanotubes Made Via a Self-Assembly Process, Z. X. Wei, M. X. Wan*, T. Lin, L. M. Dai, Adv. Mater. 2003, 15, 136.(PDF) 

[5] Synthesis and characterization of self‐doped poly (aniline-co-aminonaphthalene sulfonic acid) nanotubes, Z. X. Wei, M. X. Wan*, J. Appl. Polym. Sci. 2003, 87, 1297.(PDF) 

[4]  Studies on nanostructures of conducting polymers via self-assembly method, M. X. Wan*, Z. X. WEI, Z. M. Zhang, L. J. Zhang, K. Huang, Y. S. Yang, Synth. Met. 2003, 135, 175.(PDF) 

[3]  Nanostructures of polyaniline doped with inorganic acids, Z. M. Zhang, Z. X. Wei, M. X. Wan*, Macromolecules 2002, 35, 5937.(PDF) 

[2]  Formation mechanism of self-assembled polyaniline micro/nanotubes, Z. X. Wei, Z. M. Zhang, M. X. Wan*, Langmuir 2002, 18, 917.(PDF) 

[1]  Hollow microspheres of polyaniline synthesized with an aniline emulsion template, Z. X. Wei, M. X. Wan*, Adv. Mater. 2002, 14, 1314.(PDF)