Publication

Publication 2023.04-2024.03

  1. Prelithiated rigid polymer with high ionic conductivity as silicon-based anode binder for lithium-ion battery: Zhang J., Sun J., Zhao Y., Su Y., Meng X., Yan L., Ma T.: Journal of Colloid and Interface Science, 649, 977 - 985, 2023

  2. Interfacial defect passivation by multiple-effect molecule for efficient and stable perovskite solar cells: Ma C., Zhang C., Chen S., Ye Y., Sun L., Gao L., Sulaiman Y., Ma T., Chen M.: Solar Energy Materials and Solar Cells, 262, 112499, 2023

  3. Three birds, one-stone strategy for synthesis of hierarchically arrayed defective MnCo2O4@NF catalyst for photothermal preferential oxidation of CO in H2-rich streams: Zhou A., Guo X., Zhong S., Chen Z., Kang Q., Chen M., Jin D., Fan M., Zhou R., Ma T.: Chemical Engineering Journal, 471, 144835, 2023

  4. Sn Perovskite Solar Cells with Tin Oxide Nanoparticle Layer as Hole Transport Layer: Kitamura T., Wang L., Zhang Z., Baranwal A.K., Kapil G., Sahamir S.R., Sanehira Y., Bi H., Ma T., Shen Q., Hayase S., Ma T.: ACS Energy Letters, 8, 3565 - 3568, 2023

  5. 3D homogeneous porous copper-ceria catalyst for solar light driven photothermal CO-PROX in H2rich gas: Enhanced light absorption and abundant oxygen vacancy: Guo X., Zhong S., Ye W., Zhou A., Chen Z., Jin D., Kang Q., Fan M., Ma T.: Molecular Catalysis, 547, 113416, 2023

  6. A simple approach to synthesize NiFe-LDH-Nb2C MXene for enhanced electrochemical nitrogen reduction reactions by a synergistic effect: Hua Q., Zhu H., Xue S., Zhao F., Liang Z., Ren X., Gao L., Ma T., Liu A.: Catalysis Science and Technology, 13 ( 15 ), 4558 - 4567, 2023

  7. Construction of Cu-doped Co3O4/rGO composites with a typical buffer structure for high-performance lithium storage: Wang X., Wang R., Kang Q., Yan L., Ma T., Li D., Xu Y., Ge H.: Colloids and Surfaces A: Physicochemical and Engineering Aspects, 656, 130325, 2023

  8. Ultralow-Temperature SnO2 Electron Transport Layers Fabricated by Intermediate-Controlled Chemical Bath Deposition for Highly Efficient Perovskite Solar Cells: Gao L., He Z., Zeng K., Liu A., Jiang F., Ma T.: ChemSusChem, 16, e202600765, 2023

  9. A Simple, Mild, and Low-Cost Method for Preparation of Wood-Nigrosine in Solar-Driven Interfacial Evaporation System: Li L., Jia Y., Zeng K., He Z., Xue J., Liu A., Ma T., Gao L.: Energy Technology, 2023

  10. A two-dimensional MXene-supported CuRu catalyst for efficient electrochemical nitrate reduction to ammonia: Zhao F., Li G., Hua Q., Cao J., Song J., Gao L., Ma T., Ren X., Liu A.: Catalysis Science and Technology, 19, 2023

  11. Highly Ion-Conducting Protective Layers with Nanomicro Engineering for High-Performance Lithium Metal Anodes: You J., Hu Y., Han X., Deng L., Zheng X., Wu Q., Ma T.: ACS Sustainable Chemistry and Engineering, 11, 36, 13407 - 13414, 2023

  12. Fundamentals and Recent Progress in Magnetic Field Assisted CO2 Capture and Conversion: Zhong S., Guo X., Zhou A., Chen Z., Jin D., Fan M., Ma T.: Small, 2305533, 2023

  13. A Graphene Oxide-Supported PdCu Catalyst for Enhanced Electrochemical Synthesis of Ammonia: Liang Z., Cao J., Zhao F., Song J., Xue S., Hua Q., Ren X., Gao L., Ma T., Liu A.: ChemCatChem, 2023

  14. Versatile nicotinamide enabling dendrite-free and efficient deposition for aqueous Zn-I2 batteries: Wang H., Su Y., Yan L., Zeng X., Chen X., Xiang B., Ren H., Ma T., Ling M.: Chemical Communications, 59, 11847 - 11850, 2023

  15. Preparation of Ru-doped Cu-based catalysts for enhanced electrochemical ammonia synthesis from efficient electrocatalytic nitrate reduction: Liu A., Li G., Cao J., Zhao F., Chen X., Hua Q., Gao L., Ma T., Ren X.: Catalysis Science and Technology, 2023

  16. Interfacial Energy Level Alignment and Defect Passivation by Using a Multifunctional Molecular for Efficient and Stable Perovskite Solar Cells: Ye Y.C., Chen L., Chen X.M., Ma C.Y., Lv B.H., Wang J.Y., Dou W.D., Zhang C., Ma T.L., Tang J.X.: Advanced Functional Materials, 2023

  17. MIL-101(Fe)@Nb2C MXene for efficient electrocatalytic ammonia production: an experimental and theoretical study: Zhu H., Xue S., Zhao F., Hua Q., Liang Z., Ren X., Gao L., Ma T., Liu A.: New Journal of Chemistry, 47(32), 15302 - 15308, 2023

  18. 14.31 % Power Conversion Efficiency of Sn-Based Perovskite Solar Cells via Efficient Reduction of Sn4+: Wang L., Miao Q., Wang D., Chen M., Bi H., Liu J., Baranwal A.K., Kapil G., Sanehira Y., Kitamura T., Ma T., Zhang Z., Shen Q., Hayase S.: Angewandte Chemie - International Edition, 2023

  19. Robust lamellar Fe2O3@SnO2 heterostructure for long cycling and high-rate lithium storage: Lu Y., Wang X., Kang Q., Wang X., Wang R., Yan L., Meng X., Chang F., Gao F., Chen M., Ma T.: Colloids and Surfaces A: Physicochemical and Engineering Aspects, 669, 2023

  20. All-organic aqueous batteries consisting of quinone-hydroquinone derivatives with proton/aluminum-ion co-insertion mechanism: Su Y., Jiang H., Kang Q., Meng X., Zheng X., Lu J., Mei X., Sun X., Yan L., Ma T.: Applied Surface Science, 625, 2023

  21. Application of Transition Metal Doping in Perovskite Photovoltaic Devices: Zou W., Zhang C., Jiang H., Gao L., Fan M., Ma T.: Laser and Optoelectronics Progress, 60(9), 2023

Publication 2022.04-2023.03

  1. Integrating a three-dimensional Cu2MoS4 electrode and solid-state polymer electrolyte for sodium-ion batteries: Zhao Y., Meng X., Kang Q., Yan L., Ye X., Zhang J., Liu H., Han Q., Chen Y., Ma T.: Chemical Engineering Journal, 450, 137903, 2022

  2. Enhancing performance and stability of carbon-based perovskite solar cells by surface modification using 2-(trifluoromethylthio)aniline: Han Q., Yūta O., Wang L., Zhang C., Ma T.: Materials Today Communications, 33, 104653, 2022

  3. Molecular structure design and interface behavior of ionic liquids on metal surfaces: A theoretical study: Guan W., Zhu H., Zhang Y., Ren X., Ma T., Liu A.: Surfaces and Interfaces, 34, 2022

  4. Vanadium-free NASICON-type electrode materials for sodium-ion batteries: Wu Y., Meng X., Yan L., Kang Q., Du H., Wan C., Fan M., Ma T.: Journal of Materials Chemistry A, 10(41), 21816 – 21837, 2022

  5. Organic/inorganic hybrid quaternary ionogel electrolyte with low lithium-ion association and uniform lithium flux for lithium secondary batteries: Zhang Y., Li P., Qiao L., Sun J., Li G., Yan Y., Liu A., Ma T., Hao C.: Electrochimica Acta, 416, 140292, 2022

  6. Multiple health indicators assisting data-driven prediction of the later service life for lithium-ion batteries: Jiang H., Wang H., Su Y., Kang Q., Meng X., Yan L., Ma T.: Journal of Power Sources, 542, 231818, 2022

  7. Simulated solar light-driven photothermal preferential oxidation of carbon monoxide in H2-rich streams over fast-synthesized CuCeO2–x nanorods: Guo X., Ye W., Chen Z., Zhou A., Jin D., Ma T.: Applied Catalysis B: Environmental, 310, 121334, 2022

  8. Highly Efficient and Stable Perovskite Solar Cells Induced by Novel Bulk Organosulfur Ammonium: He Zhen., Xu C., Li L., Liu A., Ma T., Gao L.: Mater. Today Energy, 26, 101004, 2022

  9. Petal-like FexSy/WS2Heterojunction Nanosheets as an Electrocatalyst for Highly Effective Hydrogen Evolution Reaction: Chen H., Li Y., Huang H., Kang Q., Ma T.: Energy and Fuels, 36 (9), 4888 – 4894, 2022

  10. A comprehensive study on ZIF-8/SiOx/ZIF-8 core-shell composite as high-stable anode material for lithium-ion batteries: Zou W., Li T., Yao Z., Fan M., Ma T.: Journal of Electroanalytical Chemistry, 36 (9), 912, 116258, 2022

  11. Trimetal NiCoMn sulfides cooperated with two-dimensional Ti3C2 for high performance hybrid supercapacitor: Zhang J., Yao Z., Zou W., Shen Q., Fan M., Ma T.: Journal of Solid State Chemistry, 308, 122909, 2022

  12. Mechanism of oxygen reduction reaction on Ni/CNTs and Ni/X-CNTs (X=B, N, O) catalysts: a theoretical study: Zhu H., Yang Y., Kong M., Ren X., Ma T. Liu A.: Theoretical Chemistry Accounts, 141, 2022

  13. Synthesis of one-dimensional vanadium-doped CoS/Co9S8 heterojunctions as bifunctional electrocatalysts for zinc-air battery: H Huang, A Liu, Q Kang, X Ye, H Chen, WN Su, T Ma: Materials Today Energy, 25, 100968, 2022

Publication 2021.04-2022.03

  1. In situ growth of a bifunctional modification material for highly efficient electron-transportlayer-free perovskite solar cells: Gao L., Xu C., He Z., Su Y., Ma T.: New J. Chem., 46, 12767, 2022

  2. Interface Engineering and Anion Engineering of Mo-Based Heterogeneous Electrocatalysts for Hydrogen Evolution Reaction: Yin Z., Liu X., Chen S., Ma T., Li Y. : Energy and Environmental Materials, 896, 163009, 2022

  3. Perovskite Solar Cells in Space: Evaluation of Perovskite Solar Cell Hole Transport Material in Space Environment: BAUTISTA Izrael Zenar C., YANG Shuzhang, KUYYAKANONT Aekjira, IWATA Minoru, MA Tingli, CHO Mengu: TRANSACTIONS OF THE JAPAN SOCIETY FOR AERONAUTICAL AND SPACE SCIENCES, 65 (2), 95 – 107, 2022

  4. A Heat-Liquefiable Solid Precursor for Ambient Growth of Perovskites with High Tunability, Performance and Stability: He Y., Lin Z., Wang J., Zhang K., Xu X., Li Y., Huang X., Ma T., Xiao S., Yang S.: Small Methods, 2022

  5. SnOx as Bottom Hole Extraction Layer and Top in Situ Protection Layer Yields over 14% Efficiency in Sn-Based Perovskite Solar Cells: Wang L., Chen M., Yang S., Uezono N., Miao Q., Kapil G., Baranwal A.K., Sanehira Y., Wang D., Liu D., Ma T., Ozawa K., Sakurai T., Zhang Z., Shen Q., Hayase S.,: ACS Energy Letters, 3703 – 3708, 2022

  6. MOFs and their derivatives as Sn-based anode materials for lithium/sodium ion batteries: Liu K., Li C., Yan L., Fan M., Wu Y., Meng X.,Ma T.: Journal of Materials Chemistry A, 9 (48), 27234 – 27251, 2022

  7. Cascaded band gap design for highly efficient electron transport layer-free perovskite solar cells: Gao L., Xu C., Su Y., Liu A., Ma T.: Chem. Commun., 58, 6749, 2022

  8. Unveiling the Effect of Solvents on Crystallization and Morphology of 2D Perovskite in Solvent-Assisted Method: Su Y., Xue J., Liu A., Ma T., Gao L.: Molecules, 27, 1828, 2022

  9. Two-Dimensional MXene Supported Bismuth for Efficient Electrocatalytic Nitrogen Reduction: Liu A., Liang X., Zhu H., Ren X., Gao L., Gao M., Yang Y., Li G., Ma T.: Chemcatchem, 14, 2022

  10. Ru and Fe Alloying on a Two-Dimensional MXene Support for Enhanced Electrochemical Synthesis of Ammonia: Liu A., Liang X., Gao M., Ren X., Gao L.,Yang Y., Zhu H., Li G., Ma T.: Chemcatchem, 14, 2022

  11. Self-assembly synthesis of Ni-decorated Nb2C MXene as an efficient and stable catalyst towards electrochemical nitrogen reduction: Zhu H., Xue S., Liang Z., Liang X., Li G., Ren X., Gao L., Li Q., Ma T., Liu A.: Ceramics International, 48, 20599 - 20604, 2022

  12. Computational screening of Cs based vacancy-ordered double perovskites for solar cell and photocatalysis applications: Ye X., Liu A., Gao L., Zhang C., Yan L., Wen S.,Ma T.: EcoMat, e12295, 2022

  13. DFT study of X‐site ion substitution doping of Cs2PtX6 on its structural and electronic properties: Ye X., Liu A., Zhao Y., Han Q., Kitamura T., Ma T.: Int J Energy Res., 1–9, 2022

  14. Double shelled hollow CoS2@ MoS2@ NiS2 polyhedron as advanced trifunctional electrocatalyst for zinc-air battery and self-powered overall water splitting: Liu X., Yin Z., Cui M., Gao L., Liu A., Su N. W., Chen S., Ma T., Li Y. : Journal of Colloid and Interface Science, 610, 653 - 662, 2022

  15. Template synthesis of molybdenum-doped NiFe-layered double hydroxide nanotube as high efficiency electrocatalyst for oxygen evolution reaction: Yin Z., Liu X., Cui M., Cao Z., Liu A., Gao L., Ma T., Chen S., Li Y.: Materials Today Sustainability, 17, 100101, 2022

  16. Sulfur contributes to stable and efficient carbon-based perovskite solar cells: Liu C., He Z., Li Y., Liu A., Cai R., Gao L., Ma T. : Journal of Colloid and Interface Science, 605, 54 - 59, 2022

  17. A double perovskite participation for promoting stability and performance of Carbon-Based CsPbI2Br perovskite solar cells: Han Q., Yang S., Wang L., Yu F., Cai X., Ma T. : Journal of Colloid and Interface Science, 606, 800 - 807, 2022

  18. Current progress of metal sulfides derived from metal organic frameworks for advanced electrocatalysis: potential electrocatalysts with diverse applications: Liu X., Li Y., Cao Z., Yin Z., Ma T., Chen S. : Journal of Materials Chemistry A, 2022.

  19. Multifunctional porous carbon strategy assisting high-performance aqueous zinc-iodine battery: Yan L., Liu T., Zeng X., Sun L., Meng X., Ling M., Fan M., Ma T. : Carbon 187, 145-152, 2022.

  20. Interface engineering of the MoS2/NiS2/CoS2 nanotube as a highly efficient bifunctional electrocatalyst for overall water splitting: Yin Z., Liu X., Chen S., Xie H., Gao L., Liu A., Ma T., Li Y. : Materials Today Nano 17, 100156, 2022.

  21. Sn/SnOx core-shell structure encapsulated in nitrogen-doped porous carbon frameworks for enhanced lithium storage: Liu K., Meng X., Yan L., Fan M., Wu Y., Li C., Ma T. : Journal of Alloys and Compounds, 896, 163009, 2022.

  22. MXenes and their composites for lithium- and sodium-ion battery applications: Liu A., Liang X., Ma T. : Mxenes and their Composites Synthesis, Properties and Potential Applications Micro and Nano Technologies, 307-341, 2022.

  23. A cross-linked tin oxide/polymer composite gel electrolyte with adjustable porosity for enhanced sodium ion batteries: Zhao Y., Liu H., Meng X., Liu A., Chen Y., Ma T. : Chemical Engineering Journal, 431, 2, 133922, 2022.

  24. Organic ammonium salt-assisted pinhole-free CuSCN films for carbon-based perovskite solar cells: He Z., Meng F., Li L., Gao L.,Ma T.: New Journal of Chemistry, 45 ( 45 ), 21382 – 21388,2021

  25. Theoretical and experimental study of the influence of PEG and PEI on copper electrodeposition: Liang X., Ren X., He R., Ma T., Liu A.: New Journal of Chemistry, 45 ( 42 ), 19655 – 19659, 2021

  26. Investigation of the interfacial behavior of organics on sulfide semiconductor surfaces by quantum chemical calculations and molecular dynamics simulations: Zhu H., Ren X., Yan S., Liang X., Gao L., Li Y., Zhao Q.,Ma T., Liu A. Liu A.: New Journal of Chemistry, 45 ( 41 ), 19321 – 19328, 2021

  27. Recent progress in metal sulfide-based electron transport layers in perovskite solar cells: He Z., Zhou Y., Liu A., Gao L., Zhang C., Wei G.,Ma T.: Nanoscale, 13 ( 41 ), 17272 – 17289, 2021

  28. A review on electrochemical synthesized copper-based catalysts for electrochemical reduction of CO2 to C2+ products: Ye W., Guo X., Ma T.: Chemical Engineering Journal, 414 ( 15 ), 2021

  29. Theoretical study of the influence of doped oxygen group elements on the properties of organic semiconductors: Liu A., Gao M., Ma Y., Ren X., Gao L., Li Y., Ma T.: Nanoscale Adv., 3, 3100 - 3106, 2021

  30. Theoretical study of the influence of doped niobium on the electronic properties of CsPbBr3: Liang X., Ren X., Yang S., Liu L., Xiong W., Cheng L., Ma T., Liu A: Nanoscale Adv., 3, 1910 - 1916, 2021

  31. Synthesis and Surface Engineering of Composite Anodes by Coating Thin-Layer Silicon on Carbon Cloth for Lithium Storage with High Stability and Performance: Liu H., Meng X., Chen Y., Zhao Y., Guo X., Ma T.: ACS Appl. Energy Mater., 2021

  32. Interfacial engineering designed on CuSCN for highly efficient and stable carbon-based perovskite solar cells: Meng F., Gao L.,Li Y., Ma T. : Materials Today Energy, 21, 100801, 2021

  33. Two-dimensional nanosheets constituted trimetal Ni-Co-Mn sulfide nanoflower-like structure for high-performance hybrid supercapacitors: Zhang J., Li C., Fan M., Ma T., Chen H., Wang H.: Applied Surface Science, 565, 150482, 2021

  34. Over 23% power conversion efficiency of planar perovskite solar cells via bulk heterojunction design: Yang S., Han Q., Wang L., Zhou Y., Yu F., Li C., Cai X., Gao L., Zhang C., Ma T. : Chemical Engineering Journal, 426, 131838, 2021

  35. High-performance carbon-based CsPbI2Br perovskite solar cells via small molecule modification : Han Q., Yu F., Wang L., Yang S., Cai X., Meng X., Yūta O., Takeshi K., Zhang C., Ma T. : Journal of Power Sources 516, 230676, 2021

  36. Praseodymium-doped Triple-Cation Perovskite Layer for Enhanced Photovoltaic Performance : Sun L., Zhang C., Yan L., Gao L., Ma T.: Journal of Solid State Chemistry, 122826, 2021

  37. Solvent-assisted crystallization of two-dimensional Ruddlesden-Popper perovskite: Su Y., Xu C., Gao L., Wei G., Ma T. : Chemical Communications, 57 ( 81 ), 10552 – 10555, 2021

  38. A flower‐like α‐phase nickel‐cobalt‐manganese hydroxide modified with two‐dimensional Ti3C2 for high performance hybrid supercapacitors: Zhang J., Chen H., Chen Z., Li C., Meng X., Fan M., Ma T.: Electrochemical Science Advances 1 (4), e2100018, 2021

Publication 2020.04-2021.03

  1. Surface Management for Carbon-Based CsPbI2Br Perovskite Solar Cell with 14% Power Conversion Efficiency: Yu F., Han Q., Wang L., Yang S., Cai X., Zhang C.,Ma T. : Solar RPL, 5 ( 9 ), 2100404, 2021

  2. Mechanism of Enhancement in Perovskite Solar Cells by Organosulfur Amine Constructed 2D/3D Heterojunctions: He Z., Zhou Y., Su Y., Liu A., Li Y., Gao L., Ma T. : J. Phys. Chem. C, 125, 30, 16428–16434, 2021

  3. Bimetallic Sulfide SnS2/FeS2 Nanosheets as High-Performance Anode Materials for Sodium-Ion Batteries: Chen Y., Liu H., Guo X., Zhu S., Zhao Y., Iikubo S., Ma T. : ACS Appl. Mater. Interfaces, 13, 33, 39248–39256, 2021

  4. Recent Progress in MXene-Based Materials for Metal-Sulfur and Metal-Air Batteries: Potential High-Performance Electrodes : Liu A., Liang X., Ren X., Guan W., Ma T.: Electrochemical Energy Reviews, 1-33, 2021

  5. Two-Dimensional Cu2MoS4-Loaded Silicon Nanospheres as an Anode for High-Performance Lithium-Ion Batteries: Liu H., Chen Y., Zhao Y., Liu K., Guo X., Meng X., Ma T.: ACS Applied Energy Materials 4 (11), 13061-13069, 2021

  6. Recent Progresses in Carbon Counter Electrode Materials for Perovskite Solar Cells and Modules: Xu C., Zhao X., Ma J., Guo J., Ma T., Wu M.: ChemElectroChem, 2021

  7. Carrier Transport Layers-Free Perovskite Solar Cells: Wang L., Yang S., Han Q., Yu F., Zhang H., Cai X., Zhang C., Gao L., Ma T. : ChemSusChem, 2021

  8. Density functional theory study of nitrogen-doped graphene as a high-performance electrocatalyst for CO2RR : Liu A., Guan W., Wu K., Ren X., Gao L., Ma T. : Applied Surface Science, 540, 148319, 2021.

  9. DFT study of the defective carbon materials with vacancy and heteroatom as catalyst for NRR : Liu A., Yang Y., Kong D., Ren X., Gao M., Liang X., Yang Q., Zhang J., Gao L., Ma T. : Applied Surface Science, 53615, 147851, 2021.

  10. Theoretical study of the mechanism of methanol oxidation on PtNi catalyst: Liu A., Yang Y., Shi D., Ren X., Ma T.: Inorganic Chemistry Communications, 123, 108362, 2021

  11. A peanut shell-derived economical and eco-friendly biochar catalyst for electrochemical ammonia synthesis under ambient conditions: combined experimental and theoretical study: Liu A., Yang Y., Ren X., Gao M., Liang X., Ma T. : Catal. Sci. Technol., 11, 1526 - 1536, 2021

  12. A two-dimensional MXene-supported metal–organic framework for highly selective ambient electrocatalytic nitrogen reduction: Liang X., Ren X., Yang Q., Gao L., Gao M., Yang Y., Zhu H., Li G., Ma T., Liu A: Nanoscale, 13, 2843 - 2848, 2021

  13. 9,10-Anthraquinone/K2CuFe(CN)6: A Highly Compatible Aqueous Aluminum-Ion Full-Battery Configuration: Yan L., Zeng X., Zhao S., Jiang W., Li Z., Gao X., Liu T., Ji Z., Ma T., Ling M., Liang C.: ACS Appl. Mater. Interfaces, 13 ( 7 ), 8353–8360, 2021

  14. Investigation on the interfacial behavior of polyorganic inhibitors on a metal surface by DFT study and MD simulation: Liu A., Guan W., Zhao X., Ren X., Liang X., Gao L., Li Y., Ma T. : Applied Surface Science, 541, 148570

  15. Current progress of molybdenum carbide-based materials for electrocatalysis: potential electrocatalysts with diverse applications: Li Y., Yin Z., Liu X., Cui M., Chen S., Ma T.: Materials Today Chemistry, 19, 100411, 2021

  16. The sulfur-rich small molecule boosts the efficiency of carbon-based CsPbI2Br perovskite solar cells to approaching 14%: Han Q., Yang S., Wang L., Yu F., Zhang C., Wu M., Ma T.: Solar Energy, 216 ( 1 ), 351 - 357, 2021

  17. Recent Progress in Perovskite Solar Cells Modified by Sulfur Compounds : Zhou Y., Liu C., Meng F., Zhang C., Wei G., Gao L., Ma T.: Solar PRL, 5 ( 4 ) , 2000713, 2021

  18. Enhanced Device Performance with Passivation of the TiO2 Surface Using a Carboxylic Acid Fullerene Monolayer for a SnPb Perovskite Solar Cell with a Normal Planar Structure: Hamada K., Tanaka R., Kamarudin M.A., Shen Q., Iikubo S., Minemoto T., Yoshino K., Toyoda T., Ma T., Kang D.W., Hayase S.: ACS Applied Materials and Interfaces, 12 ( 15 ), 17776 – 17782, 2020.

  19. Strategies for Interfacial Modification in Perovskite Solar Cells: Meng F., Liu C., Gao L., Ma T.: Progress in Chemistry, 32 ( 6 ), 817 – 835, 2020.

  20. Significantly Enhanced V-oc and Efficiency in Perovskite Solar Cells through Composition Adjustment of SnS2Electron Transport Layers: Gao L., Liu C., Meng F., Liu A., Li Y., Li Y., Zhang C., Fan M., Wei G., Ma T.: ACS Sustainable Chemistry and Engineering, 8 ( 25 ), 9250 – 9256, 2020.

  21. Cs-Incorporated AgBiI4Rudorffite for Efficient and Stable Solar Cells: Yu F., Wang L., Ren K., Yang S., Xu Z., Han Q., Ma T.: ACS Sustainable Chemistry and Engineering, 8 ( 27 ), 9980 – 9987, 2020.

  22. Investigation of the re-dispersion of matrix Cu species in Cu: xCe1- xOnanorod catalysts and its effect on the catalytic performance in CO-PROX: Guo X., Ye W., Ma T.: Catalysis Science and Technology, 10 ( 14 ), 4766 – 4775, 2020.

  23. Energy Band Regulation in 2D Perovskite Solar Cells: Zhou Y., Hu J., Meng F., Liu C., Gao L., Ma T.: Progress in Chemistry, 32 ( 7 ), 966 – 977, 2020.

  24. Intermediate-Controlled Interfacial Engineering for Stable and Highly Efficient Carbon-Based PSCs: Meng F., Li Y., Gao L., Liu A., Li Y., Wang T., Zhang C., Fan M., Wei G., Ma T.: ACS applied materials & interfaces, 12 ( 30 ), 34479 – 34486, 2020.

  25. Synthesis of 2D layered Nb2SnC at low sintering temperature and its application for high-performance supercapacitors: Zhang Z., Huang X., Lu W., Qiu X., Ma T., Xia W.: Journal of Solid State Chemistry, 288, 121425, 2020.

  26. A facile and general procedure to hyperporous carbons: carbonization of organic zinc salts: Chen S., Huang H., Li Y., Ma T.: Materials Today Energy, 17, 100446, 2020.

  27. Significant effect of base assisted intercalates in synthesis of 2D semiconductor Ti3C2O2: Gao L., Wang N., Cao J., Li Y., Ma T.: Surfaces and Interfaces, 20, 100604, 2020.

  28. DFT study of Ru/graphene as high-performance electrocatalyst for NRR: Liu A., Gao M., Gao Y., Ren X., Yang Y., Yang Q., Li Y., Gao L., Liang X., Ma T.: Inorganic Chemistry Communications, 120, 108169, 2020.

  29. Two-dimensional CuAg/Ti3C2 catalyst for electrochemical synthesis of ammonia under ambient conditions: a combined experimental and theoretical study: Liu A., Yang Q., Ren X., Gao M., Yang Y., Gao L., Li Y., Zhao Y., Liang X., Ma T.: Sustainable Energy and Fuels, 4 ( 10 ), 5061 – 5071, 2020.

  30. Comparison of interfacial bridging carbon materials for effective carbon-based perovskite solar cells: Gao L., Hu J., Meng F., Zhou Y., Li Y., Wei G., Ma T.: Journal of Colloid and Interface Science, 579, 425 – 430, 2020.

  31. Metal-organic framework based bifunctional oxygen electrocatalysts for rechargeable zinc-air batteries: Current progress and prospects: Li Y., Cui M., Yin Z., Chen S., Ma T.: Chemical Science, 11 ( 43 ), 11646 – 11671, 2020.

  32. Hierarchical porous architectures derived from low-cost biomass equisetum arvense as a promising anode material for lithium-ion batteries: Chen Y., Liu H., Jiang B., Zhao Y., Meng X., Ma T.: Journal of Molecular Structure, 1221, 128794, 2020.

  33. Novel Lead-Free Material Cs2PtI6 with Narrow Bandgap and Ultra-Stability for Its Photovoltaic Application: Yang S., Wang L., Zhao S., Liu A., Zhou Y., Han Q., Yu F., Gao L., Zhang C., Ma T.: ACS Applied Materials and Interfaces, 12 ( 40 ), 44700 – 44709, 2020.

  34. Energy- and cost-efficient NaCl-assisted synthesis of MAX-phase Ti3AlC2 at lower temperature : Liu A., Yang Q., Ren X., Meng F., Gao L., Gao M., Yang Y., Ma T., Wu G : Ceramics International, 46(5), 6934 - 6939, 2020

  35. Facile synthesis of ZnS decorated N, S co-doped carbon polyhedron as high efficiency oxygen reduction reaction catalyst for Zn-air battery : Li Y., Wang C., Cui M., Chen S., Gao L., Liu A., Ma T. : Applied Surface Science, 509(15), 145367, 2020

  36. Several economical and eco-friendly bio-carbon electrodes for highly efficient perovskite solar cells : Gao L., Zhou Y., Meng F., Li Y., Liu A., Li Y., Zhang C., Fan M., Wei G., Ma T. : Carbon, 162, 267 - 272, 2020

  37. Hollow-structure engineering of a silicon–carbon anode for ultra-stable lithium-ion batteries : Liu H., Chen Y., Jiang B., Zhao Y., Guo X., Ma T. : Dalton Transactions, 49 ( 17 ) , 5669 – 5676, 2020.

  38. A two-dimensional Ru@MXene catalyst for highly selective ambient electrocatalytic nitrogen reduction : Liu A., Gao M., Ren X., Meng F., Yang Y., Yang Q., Guan W., Gao L., Lianga X., Ma T. : Nanoscale, 12, 10933 - 10938, 2020

  39. The reaction pathway of the CO2RR to low-carbon alcohols: a theoretical study : Liu A., Guan W., Cao Q., Ren X., Gao L., Zhao Q., Ma T. : New Journal of Chemistry, 44 ( 21 ), 8971 – 8976, 2020.

  40. Current progress in electrocatalytic carbon dioxide reduction to fuels on heterogeneous catalysts : Liu A., Gao M., Ren X., Meng F., Yang Y., Gao L., Yanga Q., Ma T. : J. Mater. Chem. A, 8, 3541–3562, 2020

  41. Recent Progress in MXene-Based Materials: Potential High-Performance Electrocatalysts : Liu A., Liang X., Ren X., Guan W., Gao M., Yang Y., Yang Q., Gao L., Li Y., Ma T. : Adv. Funct. Mater., 2003437, 2020

  42. Current Progress of Electrocatalysts for Ammonia Synthesis Through Electrochemical Nitrogen Reduction Under Ambient Conditions : Liu A., Yang Y., Ren X., Zhao Q., Gao M., Guan W., Meng F., Gao L., Yang Q., Liang X., Ma T. : ChemSusChem, 13, 1 – 24, 2020

  43. Environmental risks and strategies for long-term stability of carbon-based perovskite solar cells : Meng F., Zhou Y., Gao L., Li Y., Liu A., Li Y., Zhang C., Fan M., Wei G., Ma T. : Materials Today Energy, 2020

  44. Morphology engineering of cobalt embedded in nitrogen doped porous carbon as bifunctional oxygen electrocatalyst for Zn-air battery : Li Y., Cui M., Wang C., Chen Y., Chen S., Gao L., Liu A., Su W., Ma T. : Materials Today Energy, 17, 100455,2020.

  45. Electrocatalytic Synthesis of Ammonia Using a 2D Ti3C2 MXene Loaded with Copper Nanoparticles : Liu A., Liang X., Yang Q., Ren X., Gao M., Yang Y., Ma T. : ChemPlusChem, 202.

  46. Metal-Organic-Framework-Derived Cobalt-Doped Carbon Material for Electrochemical Ammonia Synthesis under Ambient Conditions : Liu A., Liang X., Yang Q., Ren X., Gao M., Yang Y., Ma T. : ChemElectroChem, 2020.

International Conference 2021

  1. Poster:Cs-incorporated AgBiI4 Rudorffite for Efficient and Stable Solar Cells : Yu F., Wang L., Yang S., Han Q., Ma T. : The International online conference on Hybrid materials and optoelectronic devices (HYBRIDOE) , 202012.

  2. Poster: Bifunctional Organic Disulfide for High-Efficiency and High-Stability Planar Perovskite Solar Cells : Han Q., Wang L., Yang S., Yu F., Cai X., Liu F., Zhang C, Ma T. : The International online conference on Hybrid materials and optoelectronic devices (HYBRIDOE) , 202012.

  3. Poster:A novel Lead-free material Cs2PtI6 with Narrow Bandgap and Ultra-Stable for Its Photovoltaic Application : Yang S., Wang L., Ma T. : The International online conference on Hybrid materials and optoelectronic devices (HYBRIDOE) , 202012.

Japan Conference 2021

  1. Invited:ペロブスカイト太陽電池の材料開発及び安定性の向上に関する研究 : 王 亮, 楊 樹章, 馬 廷麗 : 日本化学会 第101春季年会(2021),オンライン, 20210322.

  2. Oral: Dye Molecules Assisted CsPbIBr2 Based All Inorganic Perovskite Solar Cells for Excellent Performance : Shuzhang Y., Wang L., Ma T. : 日本化学会 第101春季年会, 202103.

  3. Oral:Equisetum arvense--Derived Hierarchical SiOx/C as Low Cost and Environmentally friendly Anodes for Lithium-Ion Batteries : Chen Y., Liu H., Jiang B., MA T. : 電気化学会88大会, 202103.

  4. Oral:Hollow-Structure Engineering of Silicon-Carbon Anode for Ultra-Stable Lithium-ion Batteries : Liu H., Chen Y., Yue Z., Jiang B., MA T. : 電気化学会88大会, 202103.

Publication 2019.04-2020.03

  1. Carbon Counter Electrodes in Dye‐Sensitized and Perovskite Solar Cells : Wu M., Sun M., Zhou H., Ma J., Ma T. : ADVANCED FUNCTIONAL MATERIALS, 30(7), 1906451, 2020

  2. Co loaded on graphene with interfacial structure as high performance catalyst for 4e− ORR: a DFT study : Liu A., Li C., Ren X., Gao L., Ma T. : Ionics, 2020

  3. Suppression of Iodide Ion Migration via Sb2S3 Interfacial Modification for Stable Inorganic Perovskite Solar Cells : Xu Z., Wang L., Han Q., Kamata Y., Ma T. : ACS Appl.Mater.Interfaces, 12(11), 12867 - 12873, 2020

  4. Excellent Moisture Stability and Efficiency of Inverted All-Inorganic CsPbIBr2 Perovskite Solar Cells through Molecule Interface Engineering: Yang S., Wang L., Gao L., Cao J., Han Q., YU F., Kamata Y., Zhang C., Fan M., Wei G., Ma T. : ACS Appl,Mater.Interfaces, 12(12), 13931 - 13940, 2020

  5. Enhanced Device Performance with Passivation of the TiO2 Surface Using a Carboxylic Acid Fullerene Monolayer for a SnPb Perovskite Solar Cell with a Normal Planar Structure : Hamada K., Tanaka R., Kamarudin A.M., Shen Q., Iikubo S., Minemoto T., Yoshino K., Toyoda T., Ma T., Kang D., Hayase S. : ACS Appl,Mater,Interfaces, 2020

  6. 2D heterostructure comprised of Ni3S2/d-Ti3C2 supported on Ni foam as binder-free electrode for hybrid supercapacitor : Zhao Y., Guo J., Liu A., Ma T. : Journal of Alloys and Compounds, 814, 152271, 2020

  7. Aurivillius Halide Perovskite: A New Family of Two-Dimensional Materials for Optoelectronic Applications : Zhao S., Lan C., Li H., Zhang C., Ma T. : Journal of Physical Chemistry C, 124(3), 1788 – 1793, 2020.

  8. A black phosphorus/Ti3C2 MXene nanocomposite for sodium-ion batteries: A combined experimental and theoretical study : Li H., Liu A., Ren X., Yang Y., Gao L., Fan M., Ma T. : Nanoscale, 11 (42), 19862 – 19869, 2019.

  9. Bifunctional Dye Molecule in All‐Inorganic CsPbIBr2 Perovskite Solar Cells with Efficiency Exceeding 10% : Yang S., Guo Z., Gao L., Yu F., Zhang C., Fan M.,Wei G., Ma T. : Solar RRL, Volume: 3, Issue: 9, 2019.

  10. Highly accessible hierarchical porous carbon from a bi-functional ionic liquid bulky gel: high performance electrochemical double layer capacitors : Yan Y., Hao X., Gao L., Lin S., Cui N., Li Y.,Hao C., Ma T.,Wang H : Journal of Chemistry A, 7, 25297–25304, 2019.

  11. A novel strategy to synthesize CoMoO4 nanotube as highly efficient oxygen evolution reaction electrocatalyst : Li Y., Wang C., Cui M., Chen S., Ma T. : Catalysis Communications, 131, 2019.

  12. La-doped SnO2 as ETL for efficient planar-structure hybrid perovskite solar cells : Xu Z., Teo S., Gao L., Guo Z., Kamata Y., Hayase S., Ma T. : Organic Electronics: physics, materials, applications, 73, 62 – 68, 2019.

  13. Large-Area Perovskite Solar Cells : Yan Y., Cao J., Meng F., Wang N., Gao L., Ma T. : Progress in Chemistry, 31(7), 1031 – 1043, 2019.

  14. Niobium Incorporation into CsPbI2Br for Stable and Efficient All-Inorganic Perovskite Solar Cells : Guo Z., Zhao S., Liu A., Kamata Y., Teo S., Yang S., Xu Z., Hayase S., Ma T. : ACS Applied Materials and Interfaces, 11(22), 19994 – 20003, 2019.

  15. Favorable growth of well-crystallized layered hybrid perovskite by combination of thermal and solvent assistance : Xue C., Shi Y., Zhang C., Lv Y., Feng Y., Tian W., Jin S., Ma T. : Journal of Power Sources, 422, 156 – 162, 2019.

  16. Electrostatic self-assembly of 2D delaminated MXene (Ti3C2) onto Ni foam with superior electrochemical performance for supercapacitor : Guo J., Zhao Y., liu A., Ma T. : Electrochimica Acta, 305, 164 – 174, 2019.

  17. Enhancing oxygen evolution reaction electrocatalytic performance with vanadium-doped Co/CoO encapsulated in carbon nanorod : Huang H., Li Y., Li W., Chen S., Wang C., Cui M., Ma T. : Inorganic Chemistry Communications, 103, 1 – 5, 2019.

  18. Xanthate-induced sulfur doped all-inorganic perovskite with superior phase stability and enhanced performance : Wang Z., Baranwal A., kamarudin M., Ng c., Pandey M., Ma T., Hayase S. : Nano Energy, 59, 258 – 267, 2019.

  19. Ultra-low-cost coal-based carbon electrodes with seamless interfacial contact for effective sandwich-structured perovskite solar cells : Meng F., Gao L., Yan Y., Cao J., Wang N., Wang T., Ma T. : Carbon, 145, 290 – 296, 2019.

  20. 2D nanoplate assembled nitrogen doped hollow carbon sphere decorated with Fe3O4 as an efficient electrocatalyst for oxygen reduction reaction and Zn-air batteries : Li Y., Huang H., Chen S., Yu X., Wang C., Ma T. : Nano Research, 12, 2774 - 2780, 2019

  21. Synthesis of monodispersed silver particles: Synthetic techniques to control shapes, particle size distribution and lightness of silver particles : Sannohe K., Ma T., Hayase S. : Adovanced Powder Technology, 30(12), 3088 - 3098, 2019

  22. Delocalized molecule surface electronic modification for enhanced performance and high environmental stability of CsPbI2Br perovskite solar cells : Wang Z., Baranwal K. A., Kamarudin A. M., Zhang P., Kapil G., Ma T., Hayase S. : Nano Energy, 66, 104180, 2019

  23. Alternative electrodes for HTMs and noble-metal-free perovskite solar cells: 2D MXenes electrodes : Cao J., Meng F., Gao L., Yang S., Yan Y., Wang N., Liu A., Li Y., Ma T. : RSC Adv., 9, 34152 - 34157, 2019

Publication 2018.04-2019.03

  1. Preparation of Perovskite Films under Liquid Nitrogen Atmosphere for High Efficiency Perovskite Solar Cells : Zhang P., Yang F., Kapil G., Ng C., Ma T., Hayase S. : ACS Sustainable Chemistry and Engineering, 7(4), 3956 – 3961, 2019.

  2. Nanowire-Templated Synthesis of FeNx-Decorated Carbon Nanotubes as Highly Efficient, Universal-pH, Oxygen Reduction Reaction Catalysts : Li Y., Huang H., Chen S., Wang C., Ma T. : Chemistry - A European Journal, 25( 10), 2637 – 2644, 2019.

  3. Killing Two Birds with One Stone: A Highly Active Tubular Carbon Catalyst with Effective N Doping for Oxygen Reduction and Hydrogen Evolution Reactions : Li Y., Huang H., Chen S., Wang C., Liu A., Ma T. : Catalysis Letters, 149(2), 486 – 495, 2019.

  4. The Role of Lanthanum in a Nickel Oxide-Based Inverted Perovskite Solar Cell for Efficiency and Stability Improvement : Teo S., Guo Z., Xu Z., Zhang C., Kamata Y., Hayase S., Ma T. : ChemSusChem, 12( 2), 518 – 526, 2019.

  5. A facile approach for the fabrication of loading-controlled Ag/C foam catalyst : Liu A., Ren X., Yao Y., Yang Q., Gao M., Yang Y., Guo J., Li Y., Gao L., Ma T. : Ionics, 25(1), 361 – 365, 2019.

  6. Free-standing NiCo2S4@VS2 nanoneedle array composite electrode for high performance asymmetric supercapacitor application : Zhang Z., Huang X., Wang H., Teo S., Ma T. : Journal of Alloys and Compounds, 771, 274 – 280, 2019.

  7. Passivation of Grain Boundary by Squaraine Zwitterions for Defect Passivation and Efficient Perovskite Solar Cells : Wang Z., Pradhan A., Kamarudin M., Pandey M., Pandey S., Zhang P., Ng C., Tripathi A., Ma T., Hayase S.: ACS Applied Materials and Interfaces, 2019, 11 (10), 10012 – 10020.

  8. Development of a mixed halide-chalcogenide bismuth-based perovskite MABiI2S with small bandgap and wide absorption range : Zhang C., Teo S., Guo Z., Gao L., Kamata Y., Xu Z., Ma T. : Chemistry Letters, 48(3), 249 - 252, 2019.

  9. Achievable high Voc of carbon based all-inorganic CsPbIBr2 perovskite solar cells through interface engineering : Guo Z., Teo S., Xu Z., Zhang C., Kamata Y., Hayase S., Ma T. : Journal of Materials Chemistry A, 7(3), 1227-1232, 2019.

  10. In-situ growth of nanowire WO2.72on carbon cloth as a binder-free electrode for flexible asymmetric supercapacitors with high performance : Huang X., Zhang Z., Li H., Wang H., Ma T. : Journal of Energy Chemistry, 29, 58-64, 2018,

  11. In-situ growth of nanowire WO2.72 on carbon cloth as a binder-free electrode for flexible asymmetric supercapacitors with high performance : Xiao Huang, Zhiguo Zhang, Huan Li, Hongxia Wang, and Tingli Ma : Journal of Energy Chemistry, 2018, DOI: 10. 1016/jechem.2018.01.024

  12. Design of a Novel and Highly Stable Lead-Free Cs2NaBiI6 Double Perovskite for Photovoltaic Application : Chu Zhang, Liguo Gao, Siohwa Teo, Zhanglin Guo, Zhenhua Xu, Shuai Zhao and Tingli Ma : Sustainable Energy & Fuels, 2018, DOI: 10.1039/C8SE00154E.

  13. Effective Oxygen Reduction and Evolution Catalysts Derived from Metal Organic Frameworks by Optimizing Active Sites : Yanqiang Li, Haibin Xu, Huiyong Huang, Liguo Gao, and Tingli Ma : J. Electrochem. Soc., 2018, 165,158-165.

  14. Indium Zinc Oxide Electron Transport Layer for High-Performance Planar Perovskite Solar Cells : Liang Wang, Fengjing Liu, Xiaoyong Cai, Tingli Ma, Chao Jiang. : Journal of Physical Chemistry C, 122(50), 28491 - 28496, 2018.

  15. One-pot synthesis of 2D Ti3C2/Ni2CO3(OH)2 composite as electrode material with superior capacity and high stability for hybrid supercapacitor : Guo J., Zhao Y., Jiang N., Liu A., Gao L., Li Y., Wang H., Ma T. : Electrochimica Acta , 292, 168 – 179, 2018.

  16. Interfacial Sulfur Functionalization Anchoring SnO2 and CH3NH3PbI3 for Enhanced Stability and Trap Passivation in Perovskite Solar Cells : Wang Z., Kamarudin M., Huey N., Yang F., Pandey M., Kapil G., Ma T., Hayase S. : ChemSusChem, 11(22), 3941 – 3948, 2018.

  17. High Electrical Conductivity 2D MXene Serves as Additive of Perovskite for Efficient Solar Cells, Guo Z., Gao L., Xu Z., Teo S., Zhang C., Kamata Y., Hayase S., Ma T., Small, 14, 47, 2018.

  18. Addition Effect of Pyreneammonium Iodide to Methylammonium Lead Halide Perovskite-2D/3D Heterostructured Perovskite with Enhanced Stability : Yang F., Zhang P., Kamarudin M., Kapil G., Ma T., Hayase S. : Advanced Functional Materials, 28, 46, 2018.

  19. In Situ Growth of a Feather-like MnO2 Nanostructure on Carbon Paper for High-Performance Rechargeable Sodium-Ion Batteries : Li H., Liu A., Zhao S., Guo Z., Wang N., Ma T. : ChemElectroChem, 5(21), 3266 – 3272, 2018.

  20. In situ fabrication of 2D SnS2 nanosheets as a new electron transport layer for perovskite solar cells : Zhao E., Gao L., Yang S., Wang L., Cao J., Ma T. : Nano Research, 11(11), 5913 – 5923, 2018.

  21. Enhanced performance of ZnO based perovskite solar cells by Nb2O5 surface passivation : Zhang P., Yang F., Kapil G., Shen Q., Toyoda T., Yoshino K., Minemoto T., Pandey S., Ma T., Hayase S. : Organic Electronics: physics, materials, applications, 62, 615 – 620, 2018.

  22. One-step salt-assisted solution combustion synthesis of Ni-based composites for use as supercapacitor electrodes : Zhao Y., Jiang N., Zhang X., Guo J., Yang Q., Gao L., Li Y., Ma T. : Journal of Alloys and Compounds, 765, 396-404, 2018.

  23. Pr/Ba cation-disordered perovskite Pr2/3Ba1/3CoO31δ as a new bifunctional electrocatalyst for oxygen reduction and oxygen evolution reactions : Zhang W., Shiraiwa M., Wang N., Ma T., Fujii K., Niwa E., Yashima M. : Journal of the Ceramic Society of Japan, 126(10), 814 – 819, 2018.

  24. Low-cost, large-scale, one-pot synthesis of C/Ni3 (NO3)2(OH)4 composites for high performance supercapacitor : Zhao Y., Jiang N., Zhang X., Guo J., Li Y., Gao L., Wang H., Ma T. : Materials Chemistry and Physics, 217, 291 – 299, 2018.

  25. Solution-Processed Air-Stable Copper Bismuth Iodide for Photovoltaics : Hu Z., Wang Z., Kapil G., Ma T., Iikubo S., Minemoto T., Yoshino K., Toyoda T., Shen Q., Hayase S. : ChemSusChem, 11(17), 2930 – 2935, 2018.

  26. Solution-Processed Air-Stable Copper Bismuth Iodide for Photovoltaics : Hu Z., Wang Z., Kapil G., Ma T., Iikubo S., Minemoto T., Yoshino K., Toyoda T., Shen Q., Hayase S. : ChemSusChem, 11(17), 2930 – 2935, 2018.

  27. Performance Enhancement of Mesoporous TiO2-Based Perovskite Solar Cells by SbI3 Interfacial Modification Layer : Zhang P., Yang F., Kamarudin M., Ng C., Kapil G., Ma T., Hayase S. : ACS Applied Materials and Interfaces, 10(35), 29630 – 29637, 2018.

  28. Environmental effects on the ionic conductivity of poly(methyl methacrylate) (PMMA)-based quasi-solid-state electrolyte : Xu T., Li J., Gong R., Xi Z., Huang T., Chen L., Ma T. : Ionics, 24(9), 2621-2629, 2018.

  29. Study to Observe the Effect of PbI2Passivation on Carbon Electrode for Perovskite Solar Cells by Quartz Crystal Microbalance System : Zhang P., Kapil G., Hamada K., Pandey S., Ma T., Hayase S. : ACS Sustainable Chemistry and Engineering, 6(8), 10221-10228, 2018.

  30. Magnesium-Doped MAPbI3Perovskite Layers for Enhanced Photovoltaic Performance in Humid Air Atmosphere : Yang F., Kamarudin M., Kapil G., Hirotani D., Zhang P., Ng C., Ma T., Hayase S. : ACS Applied Materials and Interfaces, 10(29), 24543-24548, 2018.

  31. Enhanced Crystallization by Methanol Additive in Antisolvent for Achieving High-Quality MAPbI3Perovskite Films in Humid Atmosphere : Yang F., Kamarudin M., Zhang P., Kapil G., Ma T., Hayase S. : ChemSusChem, 11(14), 2348-2357, 2018.

  32. Minute quantities of hexagonal nanoplates PtFe alloy with facile operating conditions enhanced electrocatalytic activity and durability for oxygen reduction reaction : Wang N., Li Y., Guo Z., Li H., Hayase S., Ma T. : Journal of Alloys and Compounds, 752, 23-31, 2018.

  33. First-principles study of electronic and optical properties of lead-free double perovskites Cs2NaBX6 (B = Sb, Bi; X = Cl, Br, I) : Shuai Zhao, Kumiko Yamamoto, Satoshi Iikubo, Shuzi Hayase, and Tingli Ma* : Journal of Physics and Chemistry of Solids, 2018. 117,117-121.

  34. Dependence of Acetate-Based Antisolvents for High Humidity Fabrication of CH3NH3PbI3Perovskite Devices in Ambient Atmosphere : Yang F., Kapil G., Zhang P., Hu Z., Kamarudin M., Ma T., Hayase S. : ACS Applied Materials and Interfaces, 10(19), 16482-16489, 2018,

  35. Incredible PCE Enhancement Induced by Damaged Perovskite Layers: Deeply Understanding the Working Principle of Additives in Bulk Heterojunction Perovskite Solar Cells : Liguo Gao, Likun Wang, Xiaogang Ding, Erling Zhao, Shuzhang Yang, Yingyuan Zhao, Yanqiang Li, Shufeng Wang and Tingli Ma* : J.Mater.Chem.A., 2018, 6, 4365-4373.

  36. One-Dimensional MoO2-Co2Mo3O8@C Nanorods: A Novel and High Efficient Oxygen Evolution Reaction Catalyst Derived from Metal Organic Framework Composite. Chemical Communications : Yanqiang Li, Haibin Xu, Huiyong Huang, Chao Wang, Liguo Gao, and Tingli Ma* : Chem. Commun., 2018, 54, 2739-274。

  37. Low-Temperature Processed Non-TiO2 Electron Selective Layers for Perovskite Solar Cells : Zhanglin Guo, Liguo Gao, Chu Zhang, Zhenhua Xu, and Tingli Ma* : J.Mater.Chem.A., 2018, 6, 4572-4589.

研究業績 2017年

Publication 2017

  1. A novel composite of W18O49 nanorods on reduced graphene oxide sheets based on in situ synthesis and catalytic performance for oxygen reduction reaction : Jiahao Guo,* Yantao Shi,* Huawei Zhou, Xuchun Wang and Tingli Ma* : RSC Adv., 7, 2051, 2017.

  2. Facile synthesis of N, S co-doped porous carbons from a dual-ligand metal organic framework for high performance oxygen reduction reaction catalysts : Yanqiang Li, Haibin Xu, Huiyong Huang, Liguo Gao, Yingyuan Zhao, and Tingli Ma* : Electrochimica Acta, 254, 148-154, 2017.

  3. All-solid-state flexible asymmetric supercapacitors with high energy and power densities based on NiCo2S4@MnS and active carbon : Zhiguo Zhang, Xiao Huang, Huan Li, Hongxia Wang, Yingyuan Zhao, and Tingli Ma* : J.Energy.Chem., 2017, 26, 1260-1266.

  4. Pinhole-Free Perovskite Films by Methylamine Iodide Solution-Assisted Repair for High-Efficiency Photovoltaics under Ambient Conditions : Wang Liang, Liu Fengjing, Wang Jiawei, Cai Xiaogong, Wang Gongtang, Tingli Ma* and Jiang Chao : ACS Applied Materials & Interfaces, 8, 45, 30920-30925, 2017.

  5. A novel composite of W18O49 nanorods on reduced graphene oxide sheets based on in situ synthesis and catalytic performance for oxygen reduction reaction : Guo Jiahao, Shi YanTao, Zhou Huawei, Wang Xunchun, and Tingli Ma* : RSC Advances, 7, 4, 2051-2057, 2017.

  6. Transparent conductive oxide-less back cintact dye-sensitized solar cells using flat titanium sheet with microholes for photoanode farication : Azwar, Baranwal Ajay Kumar, Nakamura Masaki, Shigeki Fujisawa, Pandey Shyam S, Tingli Ma* and Hayase Shuzi : Journal of Photonics for Energy, 7, 1, 2017.

  7. Advance and Obstacles on Perovskite Solar Cell Research from Material Properties to Photovoltaic Function : Bisquert Juan*, Qi Yabing, Tingli Ma and Yan Yanfa : ACS Energy Letters, 2, 2, 520-523, 2017.

  8. One-Stage Method For Fabricating Superhydrophobic Stainless Steel Surface and Its Anti-Corrosion Preformance : Gao Liguo, Yang Shuzhang, Yang Hongjing, and Tingli Ma* : Advance Engineering Materials. 219, 2, 2017.

  9. Transparent Conductive Oxide Layer and Hole Selective Layer Free Back-Contacted Hybrid Perovskite Solar Cell : Hu Zhaosheng, Kapil Gauray, Shimazaki Hiromitsu, Pandey Shyam Sudhir, Tingli Ma* and Shuzi Hayasei : Journal of Physical Chemistry C. 121, 8, 4214-4219. 2017.

  10. Low-temperature processed compact layer for perovskite solar cells with negligible hysteresis : Wang Liang, Liu Fengjing, Cai Xiaoyong, Wang Gongtang, and Tingli Ma* : Electrochimica Acta. 235, 640-645, 2017.

  11. Current Advancements in Material Research and Techniques Focusing on Lead-free Perovskite Solar Cells : Chu Zhang, Liguo Gao, Shuzi Hayasei, and Tingli Ma* : Chemistry Letter, 46(9), 1276-1284, 2017.

  12. Metal?organic framework derived hierarchical porous TiO2 nanopills as a super stable anode for Na-ion batteries : Huan Li, Zhiguo Zhang, Xiao Huang, Tongbin Lan, Mingdeng Wei, and Tingli Ma* : J. Energy. Chemistry., 26(4),667-672, 2017.

  13. Effect of lead-free (CH3NH3)3Bi2I9 perovskite addition on spectrum absorption and enhanced photovoltaic performance of bismuth triiodide solar cells : Chunfeng Lan, Jingting Luo, Shuai Zhao, Chu Zhang, Weiguo Liu, Shuzi Hayase, and Tingli Ma* : J. All. com., 701, 834-840, 2017.

  14. 3-D honeycomb NiCo2S4 with high electrochemical performance used for supercapacitor electrodes : Zhiguo Zhang, Xiao Huang, Huan Li, Yingyuan Zhao, and Tingli Ma* : Applied Surface Science, 400, 238?244, 2017.

研究業績 2016年

Publication 2016

  1. Concentration gradient controlled growth of large-grain CH3NH3PbI3 films and enhanced photovoltaic performance of solar cells in ambient conditions : Chunfeng Lan, Shuai Zhao, Chu Zhang, Weiguo Liu, Shuzi Hayase and Tingli Ma* : CrystEngComm, 2016,18, 9243-9251

  2. Strategic improvement of the long-term stability of perovskite materials and perovskite solar cells : Tingting Xu, Lixin Chen, Zhanhu Guo, and Tingli Ma* : Physical Chemistry Chemical Physics, 2016, 2016,18, 27026-27050

  3. Recent progress of silicon composites as anode materials for secondary batteries : Jingjing Wang, Tingting Xu, Xiao Huang, Huan Li, and Tingli Ma* : RSC Advances, 2016, 6, 87778-87790

  4. Oxygen vacancy formation and migration in double perovskite Sr2CrMoO6: a first-principles study : Shuai Zhao, Liguo Gao, Chunfeng Lan, Shyam S. Pandey, Shuzi Hayase, Tingli Ma* : RSC Advances, 2016.

  5. First principles analysis of oxygen vacancy formation and migration in Sr2BMoO6 (B = Mg, Co, Ni) : Shuai Zhao, Liguo Gao, Chunfeng Lan, Shyam S. Pandey, Shuzi Hayase, Tingli Ma* : RSC Advances, 2016, 6, 31968-31975.

  6. Graphene-mediated highly-dispersed MoS2 nanosheets with enhanced triiodide reduction activity for dye-sensitized solar cells : Chang Yua, Xiangtong Meng, Xuedan Song, Suxia Liang, Qiang Dong, Gang Wang, Ce Hao, Xichuan Yang, Tingli Ma, Pulickel M. Ajayanb, Jieshan Qiu : Carbon, Volume 100, April 2016, Pages 474?483.

  7. Earth-abundant and nano-micro composite catalysts of Fe3O4@reduced graphene oxide for green and economical mesoscopic photovoltaic devices with high efficiencies up to 9% : Huawei Zhou, Jie Yin*, Zhonghao Nie, Zhaojin Yang, Dongjie Li, Junhu Wang, Xin Liu, Changzi Jin, Xianxi Zhang*, Tingli Ma* : J. Mater. Chem. A, 2016, 4, 67-73.

  8. Catalytic activities enhanced by abundant structural defects and balanced N distribution of N-doped graphene in oxygen reduction reaction : Xiaogong Bai, Yantao Shi, Jiahao Guo, Liguo Gao, Kai Wanga, Yi Du, Tingli Ma* : Journal of Power Sources, Volume 306, 29 February 2016, Pages 85?91.

  9. Investigation on structures, band gaps, and electronic structures of lead free La2NiMnO6 double perovskite materials for potential application of solar cell : Chunfeng Lan, Shuai Zhao, Tingting Xu, Jie Ma, Shuzi Hayase, Tingli Ma* : Journal of Alloys and Compounds 2016, 655, pp 208?214.

  10. Amorphous Inorganic Electron-Selective Layers for Efficient Perovskite Solar Cells: Feasible Strategy Towards Room-Temperature Fabrication : Kai Wang, Yantao Shi, Bo Li, Liang Zhao, Wei Wang, Tingli Ma* : Advanced Materials, 2016, 28, 1891?1897 , DOI: 10.1002/adma.

International Conference 2016

  1. Kai Wang, Yangtao Shi,Tingli Ma, Development nano functional materials for perovskite solar cell, EMN Photovoltaics Meeting 2016,Hong Kong China

Japan Conference 2016

  1. Tingli Ma.,ECSJ Spring Meeting 2016,Osaka Japan

  2. Tingli Ma., The 96th CSJ Annual Meeting 2016, Kyoto Japan

  3. Tingli Ma.,JSAP Spring Meeting 2016 2016,Tokyo Japan

研究業績 2015年

Publication 2015

  1. Combining novel device architecture and NIR dye towards the fabrication of transparent conductive oxide-less tandem dye sensitized solar cells : Ajay Kumar Baranwal, Naotaka Fujikawa, Azwar Hayat, Yuhei Ogomi, Shyam S. Pandey, Tingli Ma and Shuzi Hayase* : Applied Physics Express, Volume 8, Number 10.

  2. Amorphous Inorganic Electron-Selective Layers for Efficient Perovskite Solar Cells: Feasible Strategy Towards Room-Temperature Fabrication : Kai Wang,Yantao Shi,Bo Li,Liang Zhao,Wei Wang,Xiangyuan Wang,Xiaogong Bai,Shufeng Wang,Ce Hao, Tingli Ma* : Adv. Mater., 10.1002/adma.201505241.

  3. Low-Temperature and Solution-Processed Amorphous WOX as Electron-Selective Layer for Perovskite Solar Cells : Kai Wang, Yantao Shi*, Qingshun Dong, Yu Li, Shufeng Wang, Xufeng Yu, Mengyao Wu, Tingli Ma* : J. Phys. Chem. Lett., 2015, 6 (5), pp 755?759.

  4. Counter electrode materials combined with redox couples in dye- and quantum dot-sensitized solar cells : Mingxing Wu,* Xiao Lin, Yudi Wang, Tingli Ma* : J. Mater. Chem. A, 2015,3, 19638-19656.

  5. Insight into Perovskite Solar Cells Based on SnO2 Compact Electron-Selective Layer : Qingshun Dong, Yantao Shi*, Kai Wang, Yu Li, Shufeng Wang, Hong Zhang, Yujin Xing, Yi Du, Xiaogong Bai, Tingli Ma*: J. Phys. Chem. C, 2015, 119 (19), pp 10212?10217.

  6. Perovskite Solar Cell Using a Two-Dimensional Titania Nanosheet Thin Film as the Compact Layer : Can Li, Yahui Li, Yujin Xing, Zelin Zhang, Xianfeng Zhang, Zhen Li, Yantao Shi, Tingli Ma, Renzhi Ma, Kunlin Wang, and Jinquan Wei* : ACS Appl. Mater. Interfaces, 2015, 7 (28), pp 15117?15122.

  7. CH3NH3PbI3 and CH3NH3PbI3?xClx in Planar or Mesoporous Perovskite Solar Cells: Comprehensive Insight into the Dependence of Performance on Architecture : Yantao Shi*, Yujin Xing, Yu Li, Qingshun Dong, Kai Wang, Yi Du, Xiaogong Bai, Shufeng Wang, Zhijian Chen, Tingli Ma* : J. Phys. Chem. C, 2015, 119 (28), pp 15868?15873.

  8. Synthesis of highly effective Pt/carbon fiber composite counter electrode catalyst for dye-sensitized solar cells : Hongyue Guo, Yajing Zhu, Wenyan Li, Haikuo Zheng, Kezhong Wu, Keqiang Ding, Bei Ruan, Anders Hagfeldt, Tingli Ma, Mingxing Wu* : Electrochimica Acta, Volume 176, 10 September 2015, Pages 997?1000.

  9. Transition metal selenides as efficient counter-electrode materials for dye-sensitized solar cells : Jiahao Guo, Suxia Liang, Yantao Shi,* Ce Hao, Xuchun Wang, Tingli Ma* : Phys. Chem. Chem. Phys., 2015,17, 28985-28992

  10. Electrocatalytic properties of iron chalcogenides as low-cost counter electrode materials for dye-sensitized solar cells : Jiahao Guo, Suxia Liang, Yantao Shi,* Bo Li, Ce Hao, Xuchun Wang, Tingli Ma* : RSC Adv., 2015,5, 72553-72561

  11. Antisolvent diffusion-induced growth, equilibrium behaviours in aqueous solution and optical properties of CH3NH3PbI3 single crystals for photovoltaic applications : Huawei Zhou, Zhonghao Nie, Jie Yin, Yuanwei Sun, Hongyan Zhuo, Daqi Wang, Dacheng Li, Jianmin Dou, Xianxi Zhang, Tingli Ma* : RSC Adv., 2015,5, 85344-85349.

  12. First principles study on the electronic and optical properties of B-site ordered double perovskite Sr2MMoO6 (M=Mg, Ca, and Zn) : Shuai Zhao, Chunfeng Lan, Jie Ma, Shyam S. Pandey, Shuzi Hayase, Tingli Ma* : Solid State Communications 2015, 213?214, pp 19?23.

  13. Dye-sensitized solar cells based on axially ligated phosphorus-phthalocyanine dyes : Azwar Hayat, Gururaj M. Shivashimpi, Terumi Nishimura, Naotaka Fujikawa, Yuhei Ogomi, Yoshihiro Yamaguchi, Shyam S. Pandey, Tingli Ma and Shuzi Hayase* : Appl. Phys. Express 8 047001.

  14. Low-Temperature Processed and Carbon-Based ZnO/CH3NH3PbI3/C Planar Heterojunction Perovskite Solar Cells : Huawei Zhou, Yantao Shi, Kai Wang, Qingshun Dong, Xiaogong Bai, Yujin Xing, Yi Du, Tingli Ma* : J. Phys. Chem. C, 2015, 119 (9), pp 4600?4605.

  15. Effects of 4-tert-butylpyridine on perovskite formation and performance of solution-processed perovskite solar cells : Yantao Shi, Tingli Ma* : J. Mat. Cheml. A., 2015, DOI: 10.1039/C5TA05988G.

  16. Synthesis of CH3NH3SrxPb(1-x)I3 with Less Pb Content and Its Application in All-Solid Thin Film Solar Cells : XiaoGong Bai, YanTao Shi, Kai Wang, QingShun Dong, YuJin Xing, Hong Zhang, Liang Wang,Tingli Ma* : Acta Phys. -Chim. Sin. 2015, 31, 285. DOI:10.3866/PKU.WHXB201412241.

International Conference 2015

  1. Kai Wang, Qingshun Dong, Chunfeng Lan, Shuai Zhao, Tingli Ma* Low temperature and solution processed electron selective layer for flexible perovskite solar cells, XXIV Internatonal Materialss Reseach Congress 2015, Mexico

  2. Tingli Ma*, Kai Wang, Yantao Shi. Development of nanomaterials and application in DSSCs and Perovskite solar cells The Second Conference on New Generation Solar Cells. 2015,China

  3. Kai Wang, Yangtao Shi, Tingli Ma*, WOx and SnO2 as Electron Selective Layer for Perovskite Solar Cells Base on New Pt-like Counter Electrodes The 7th International Conference on Hybrid and Organic Photovoltaics (HOPV 2015) 2015, Roma, Italy

Japan Conference 2015

  1. Tingli Ma., JSAP Autumn Meeting 2015, Nagoya Japan

  2. Tingli Ma., ECSJ Autumn Meeting 2015, Saitama Japan

研究業績 2014年

Publication 2014

  1. Hole-Conductor-Free, Metal-Electrode-Free TiO2/CH3NH3PbI3 Heterojunction Solar Cells Based on a Low-Temperature Carbon Electrode : Huawei Zhou, Yantao Shi*, Qingshun Dong, Hong Zhang, Yujin Xing, Kai Wang, Yi Du, and Tingli Ma* : J. Phys. Chem. Lett. 2014, DOI:10.1021/jz5017069.(IF:6.687)

  2. Surface Oxygen Vacancy-Dependent Electrocatalytic Activity of W18O49 Nanowires : Huawei Zhou,?Yantao Shi*, Qingshun Dong, Jian Lin, Aiqin Wang and?Tingli Ma* : The Journal of Physical Chemistry C.,?2014, DOI:10.1021/jp504368v.(IF:4.835)

  3. A green route and rational design for ZnO-based high-efficiency photovoltaics : Yantao Shi, Chao Zhu,?Yanxiang Wang*, Lin Wang, Yi Du, Junfu Gu, Tingli Ma, Anders Hagfeldt and?Ning Wang* : Nanoscale.,?2014, 6, 5093.(IF:6.739)

  4. Zn2SnO4-Based Dye-Sensitized Solar Cells: Insight into Dye-Selectivity and Photoelectric Behaviors : Kai Wang,?Yantao Shi*, Wei Guo,Xiaoqiang Yu,?Tingli Ma* : Electrochimica Acta.,?2014, 135, 242.(IF:4.086)

  5. Iron oxide nanostructures as highly efficient heterogeneous catalysts for mesoscopic photovoltaics : Liang Wang,?Yantao Shi*, Hong Zhang, Xiaogong Bai, Yanxiang Wang and?Tingli Ma* : Journal of Materials Chemistry A.,2014, 2, 15279.(IF:6.626)

  6. Screen-printed Pt counter electrodes exhibiting high catalytic activity : Chunyu Zhao,?Yantao Shi*, Zhiyong Zhong,?Tingli Ma* : Chinese Journal of Catalysis.,2014, 35, 219.

  7. Dual Functional Additive for HTM Layer in Perovskite Solar Cells : Hong Zhang,?Yantao Shi*, Feng Yan, Liang Wang, Kai Wang, Yujin Xing, Qingshun Dong, and?Tingli Ma* : Chem. Commun.,?2014,?50, 5020-5022.(IF:6.718)

  8. Single-Atom Catalysis in Mesoscopic Photovoltaics: The Principle of Utility Maximization : Yantao Shi*, Chunyu Zhao, Haisheng Wei, Jiahao Guo, Suxia Liang, Aiqin Wang, Tao Zhang*, Jingyue Liu, and Tingli Ma* : Adv. Mater. 2014,26, 8147. DOI: 10.1002/adma.201402978

  9. Pt-Free Counter Electrode for Dye-Sensitized Solar Cells with High Efficiency : Sining Yun,* Anders Hagfeldt, and Tingli Ma : Adv. Mater. 2014.(IF:13.8)

  10. Interlaced W18O49 nanofibers as a superior catalyst for the counter electrode of highly efficient dyesensitized solar cells : Huawei Zhou,Yantao Shi,, Qingshun Dong,Yanxiang Wang,Chao Zhu,Liang Wang,Ning Wang,Ying Wei, Shengyang Tao and Tingli Ma* : J. Mater. Chem. A, 2014,2(12), 4347-4354.(IF:6.101)

  11. Composite Catalyst of Rosin Carbon/Fe3O4: Highly Efficient Counter Electrode for Dye-Sensitized Solar Cell : Liang Wang, Yantao Shi, Yanxiang Wang, Hong Zhang, Hua wei Zhou, Ying Wei, Shengyang Tao and Tingli Ma* : Chem. Commun., 2014,501701-1703.(IF:6.378)

  12. From Marine Plant to Photovoltaic Devices : Liang Wang, Yantao Shi*, Xiaogong Bai, Yujin Xing, Hong Zhang, Lin Wang, Wei Guo, Ning Wang, Tingli Ma*,and Michael Gratzel : Energy & Environmental Science, 2014.(IF:11.653)

  13. Selenium as a photoabsorber for inorganic-organic hybrid solar cells : Kai Wang, Yantao Shi*, Hong Zhang, Yujin Xing, Qingshun Dong, and Tingli Ma* : PCCP. 2014, 16, 23316. DOI: 10.1039/c4cp02821j

  14. Composite Catalyst of Rosin Carbon/Fe3O4: Highly Efficient Counter Electrode for Dye-Sensitized Solar Cell : Liang Wang,?Yantao Shi, Yanxiang Wang, Hong Zhang, Hua wei Zhou, Ying Wei, Shengyang Tao and?Tingli Ma* : Chem. Commun.,?2014, 50, 1701-1703.(IF:6.378)

  15. Pt-Free Counter Electrode for Dye-Sensitized Solar Cells with High Efficiency : Sining Yun, Tingli Ma* : Adv. Mater., 2014, 26, 6720-2727

International Conference 2014

  1. Kai Wang, Qingshun Dong, Yantao Shi, Chunfeng Lan, Shuai Zhao, Tingli Ma*, Low-temperature Processed and Carbon-based Flexible Perovskite Solar Cells with High Stability., MRS.Spring meeting, 2014 Boston.U.S

  2. Liang Wang, Huawei Zhou, Jiaohao, Guo, Yangtao Shi, Shuzi, Hayase, Tingli Ma*, Low-cost Dye-sensitized Solar Cells Base on New Pt-like Counter Electrodes The 6th International Conference on Hybrid and Organic Photovoltaics (HOPV 2014) 2014, Lausanne, Switzerland.

  3. Md. Zaman Molla, Gaurav Kapil, Qi Zhao, Ao Li, Yuexian Cao, Yuhei Ogomi, Shyam. S. Pandey, Shigeki Fujisawa, Tingli Ma*, and Shuzi Hayase, Cylindrical TCO-Less dye-sensitized solar cells with back contact structure, The 15th IUMRS-International Conference in Asia (IUMRS-ICA 2014) 2014 Fukuoka, Japan

  4. Hong Zhang, Yantao Shi, and Tingli Ma*, Dual Functional Additive for Perovskite Solar Cells, The 20th International Conference on Photochemical Conversion and Storage of Solar Energy (IPS-20)

研究業績 2013年

Publication 2013

  1. From Marine Plant to Photovoltaic Devices : Liang Wang, Yantao Shi*, Xiaogong Bai, Yujin Xing, Hong Zhang, Lin Wang, Wei Guo, Ning Wang, Tingli Ma*
    , and Michael Gratzel Energy & Environmental Science, 2013,DOI:10.1039/C3EE42767F.(IF:11.653)

  2. Morphology dependence of performance of counter electrodes for dye-sensitized solar cells of hydrothermally prepared hierarchical Cu2ZnSnS4 nanostructures : Yahong Xie*, Chunyang Zhang, Fan Yue, Yun Zhang, Yantao Shi and Tingli Ma* : RSC Advances, 2013, 3, 23264-23268.(IF:2.562)

  3. Metal Oxide/Carbide/Carbon Nanocomposites: In Situ Synthesis, Characterization, Calculation and its Application as Efficient Counter Electrode Catalyst for Dye-Sensitized Solar Cells : Sining Yun*, Hong Zhang, Huihai Pu, Junhong Chen, Anders Hagfeldt and Tingli Ma* : Advanced Energy Materials, 2013, doi:10.1002/aenm.201300242, (IF:10.043)

  4. Highly efficient telluride electrocatalysts for use as Pt-free counter electrodes in dye-sensitized solar cells : Jiahao Guo, Yantao Shi*, Yuting Chu and Tingli Ma* : Chem. Commun., 2013, 49, 10157-10159.(IF:6.378)

  5. Cost-effective and morphology-controllable niobium diselenides for highly efficient counter electrodes of dye-sensitized solar cells : Jiahao Guo, Yantao Shi*, Chao Zhu, Lin Wang, Ning Wang and Tingli Ma* : J. Mater. Chem. A, 2013, 1: 11874. (IF:6.101)

  6. Economical, green and dual-function pyridyl iodides as electrolyte components for high efficiency dye-sensitized solar cells : Hong Zhang, Yantao Shi*, Liang Wang, Chaolei Wang, Huawei Zhou, Wei Guo and Tingli Ma* : Chem. Commun., 2013, 49(79):9003-9005.(IF:6.37)

  7. Solid-State Synthesis of ZnO Nanostructures for Quasi-Solid Dye-Sensitized Solar Cells with High Efficiencies up to 6.46% : Yantao Shi*, Kai Wang , Yi Du , Hong Zhang , Junfu Gu , Chao Zhu , Lin Wang , Wei Guo , Anders Hagfeldt , Ning Wang , and Tingli Ma* : Adv Mater., 2013, 25(32):4413-4419.(IF:14.829))

  8. Notable catalytic activity of oxygen-vacancy-rich WO2.72 nanorod bundles as counter electrodes for dye-sensitized solar cells : Huawei Zhou, Yantao Shi*, Liang Wang, Hong Zhang, Chunyu Zhao, Anders Hagfeldtb and Tingli Ma* : Chem. Commun. 2013, 49, 7626-7628.(IF:6.378)

  9. First Application of Bis(oxalate)borate Ionic Liquids (ILBOBs) in High- Performance Dye-sensitized Solar Cells : Liang Wang, Hong Zhang, Rile Ge, Chaolei Wang, Wei Guo, Yantao Shi, Yanan Gao* and Tingli Ma* : RSC Adv., 2013, 3(31):12975.(IF:2.562)

  10. Ultrarapid Sonochemical Synthesis of ZnO Hierarchical Structures: From Fundamental Research to High Efficiencies up to 6.42% for Quasi-Solid Dye-Sensitized Solar Cells : Yantao Shi, Chao Zhu, Lin Wang, Chunyu Zhao, Wei Li, Kwok Kwong Fung, Tingli Ma* : Anders Hagfeldt, Ning Wang* Chemistry of Materials, 2013, 25(6):1000-1012. (IF:8.238)

  11. Highly Efficient and Low Cost Pt-based Binary and Ternary Composite Catalysts as Counter Electrode for Dye-Sensitized Solar Cells : Yudi Wang, Chunyu Zhao, Mngxing Wu, Wei Liu and Tingli Ma* : Electrochimica Acta, 2013, 105:671-676.(IF:3.777)

  12. Highly Stable Gel-State Dye-Sensitized Solar Cells Based on High Soluble Polyvinyl Acetate : Liang Wang, Hong Zhang, Chaolei Wang and Tingli Ma* : ACS Sustainable Chem. Eng., 2013, 1(2):205-208.

  13. Printable fabrication of Pt-and-ITO free counter electrode for all flexible quasi-solid dye-sensitized solar cells : Huawei Zhou, Yantao Shi* , Da Qin, Jiang An, Lingling Chu, Chaolei Wang, Yudi Wang, Wei Guo, Liang Wang and Tingli Ma* : J. Mater. Chem. A, 2013, 1(2):205-208.(IF:6.101)

  14. Printable electrolytes for highly efficient quasi-solid-state dye-sensitized solar cells : Chaolei Wang, Liang Wang, Yantao Shi, Hong Zhang and Tingli Ma* : Electrochimica Acta, 2013, 91:302-306

  15. A new type of lowcost counter electrode catalyst based on platinum nanoparticles loaded onto silicon carbide (Pt/SiC) for dye-sensitized solar cells : Sining Yun*, Liang Wang, Chunyu Zhao, Yanxiang Wang and Tingli Ma* : Phys. Chem. Chem. Phys., 2013, 15(12):4286-4290.(IF:3.829)

  16. Economical hafnium oxygen nitride binary/ternary nanocomposite counter electrode catalysts for high-efficiency dye-sensitized solar cells : Sining Yun*, Huawei Zhou, Liang Wang, Hong Zhang and Tingli Ma* : J. Mater. Chem. A, 2013, 1(4):1341.(IF:6.101)

  17. Pt-like Behavior of High-Performance Counter Electrodes Prepared from Binary Tantalum Compounds Showing High Electrocatalytic Activity for Dye-Sensitized Solar Cells : Sining Yun*, Mingxing Wu, Yudi Wang, Jing Shi, Xiao Lin, Prof. Anders Hagfeldt and Tingli Ma* : ChemSusChem., 2013, 6(3):411-416. (IF:7.475)

International Conference 2013

  1. Tingli Ma*,et al, Long-term stability of low-cost dye-sensitized solar cells prepared by all screen-printing method, PVSEC-23, 2013, Taiwan

  2. Tingli Ma*,et al, Dye-sensitized Solar Cells from Fundamental Research to Application POEM (International Photonics and OptoElectronics Meetings) 2013, May 24-27,2013 ,WuHan China

  3. Tingli Ma*,et al, Pt-free Catalysts Used as Counter Electrodes in Solar Cell. SISF (International Solar Forum)2013, 2013, Seoul, Korea

  4. Tingli Ma*,et al, Dye-sensitized Solar Cells from Fundamental Research to Application. Tingli Ma,PASEC-2(Photocatalysis and Solar Energy Conversion: Development of Materials and -Nanomaterials ) 2013 Japan

  5. Tingli Ma*,et al High Efficiency and Low Cost Dye-sensitized Solar Cells. Tingli Ma, Proceedings of International Conference on Green Energy and Technology(ICGET) 2013,Japan

研究業績 2012年

Publication 2012

  1. An Autocatalytic Factor in the Loss of Efficiency in Dye-Sensitized Solar Cells.
    Mingxing Wu, Yudi Wang, Xiao Lin, Anders Hagfeldt and Tingli Ma*
    ChemCatChem. 2012, 4,1255-1258.

  2. Transparent Flexible Pt Counter Electrodes for High Performance Dye-Sensitized Solar Cells.
    Yudi Wang, Chunyu Zhao, Da Qin, Mingxing Wu, Wei Liu, Tingli Ma*
    J. Mater. Chem. 2012, 22, 22155-22159.

  3. Enhanced Photoconversion Efficiency of All-Flexible Dye-Sensitized Solar Cells Based on a Ti Substrate with TiO2 Nanoforest Underlayer.
    Jiang An, Wei Guo, Tingli Ma*
    SMALL. 2012, 8, 22, 3427?3431.

  4. Optimization of the Performance of Dye-Sensitized Solar Cells Based on Pt-Like TiC Counter Electrodes : Yudi Wang, Mingxing Wu, Xiao Lin, Anders Hagfeldt, Tingli Ma* : European Journal of Inorganic Chemistry. 2012, 22, 3557-3561.

  5. Highly efficient catalysts for Co(II/III) redox couples in dye-sensitized solar cells : Liang Wang , Eric Wei-Guang Diau , Mingxing Wu , Hsueh-Pei Lu and Tingli Ma* : Chem. Commun. 2012, 48, 2600-2602.

  6. Improvement of adhesion of Pt-free counter electrodes for low-cost dye-sensitized solar cells : Yurong Gao, Lingling Chu, Mingxing Wu, Linlin Wang, Wei Guo and Tingli Ma* : Journal of Photochemistry and Photobiology A:Chemistry. 2012, 245, 66-71.

  7. Fabrication and Application of a Carbon Counter Electrode with Excellent Adhesion Properties for Dye-Sensitized Solar Cells : Ling-Ling CHU, Yu-Rong GAO, Ming-Xing WU, Lin-Lin WANG, Tingli Ma* : Acta Phys. Chim. Sin., 2012, 28(07): 1739-1744.

  8. Highly efficient inorganic?organic heterojunction solar cells based on SnS-sensitized spherical TiO2 electrodes : Wei Guo, Yihua Shen, Mingxing Wu and Tingli Ma* : Chem. Commun. 2012, 48, 6133-6135.

  9. SnS-Quantum Dot Solar Cells Using Novel TiC Counter Electrode and Organic Redox Couples : Wei Guo, Yihua Shen, Mingxing Wu, LinLin Wang and Tingli Ma* : Chemistry - A European Journal. 2012, 18, 7862-7868.

  10. High-performance phosphide/carbon counter electrode for both iodide and organic redox couples in dye-sensitized solar cells : Mingxing Wu, Jin Bai, Yudi Wang, Anjie Wang, Xiao Lin, Liang Wang, Yihua Shen, Zeqing Wang, Anders Hagfeldt and Tingli Ma*: J. Mater. Chem. 2012, 22, 11121-11127.

  11. Economical Pt-Free Catalysts for Counter Electrodes of Dye-Sensitized Solar Cells : Mingxing Wu, Xiao Lin, Yudi Wang, Tingli Ma, et al. Tingli Ma* : J. Am. Chem. Soc., 2012, 134.3419-342.

  12. Pt-free Catalysts Used as Counter Electrodes in Dye-sensitized Solar Cells : Mingxing Wu, Tingli Ma* : ChemSusChem, 2012, DOI: 10.1002/cssc.201100676.

  13. Several Highly Efficient Catalysts for Pt-free and FTO-free Counter Electrodes of Dye-Sensitized Solar Cells : Yudi Wang, Mingxing Wu, Xiao Lin, Tingli Ma* : J. Mater. Chem. 2012, 22, 4009-4014.

International Conference 2012

  1. Tingli Ma,et al Enhanced Photoconversion Efficiency of All-Flexible Dye-Sensitized Solar Cells Based on a Ti Substrate with TiO2 Nanoforest Underlayer. 19th International Conference on Photochemical Conversion and Storage of Solar Energy(IPS-19)2012, USA

  2. Tingli Ma,et al Hybrid Dye-sensitized Solar Cell based on dyes of Porphyrins and Phthalocyanines. 7th International Conference on Porphyrins and Phthalocyanines (ICPP-7)2012,Korea

  3. Tingli Ma High Efficiency and Low Cost Dye-sensitized Solar Cells. International Conference on Functional Organic Materials and Related Devices. 2012,Taiwan