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2023

136. H.R. Shen, X.M. Zheng, Q.L. Kang, P. Dai, X.Y. Han, M.G. Chen, B. Muniyandi, Q. Wu, G.P. Tu, P.Y. Zhang, R. Huang, L. Deng, J.T. Li, L. Huang, S.G. Sun, High-performance and sodiation mechanism of a pulse potential-electrodeposited Sb-Zn alloy as an anode for sodium-ion batteries, Appl. Surf. Sci.2023; 609: 155243.

135. H.R. Shen, X.Y. Han, X.M. Zheng, B. Muniyandi, J.K. Wang, Q.L. Kang, M.G. Chen, Q. Wu, P.Y. Zhang, One-step electrochemical synthesis and optimization of Sb-Co-P alloy anode for sodium ion battery, Electrochimica Acta.2023; 438: 141529. 

134. Y.T. Su, H.M. Jiang, Q.L. Kang, X,H. Meng, X.M. Zheng, J.F. Lu, X.K. Mei, X.D. Sun, L.J. Yan*, T.L. Ma*. All-organic aqueous batteries contisting of quinone-hydroquinone derivatives with proton/aluminum-ion co-insertion mechanism, Applied Surface Science, 2023,157174.

133. Zhang J, Yao Z, Fan M, et al. In situ morphological evolution of Ni3S2/MoS2 grow on Ni foam as binder-free electrode for hybrid supercapacitors[J]. Ionics, 2023, 29(5): 2043-2052.

132. Su Y, Jiang H, Kang Q, et al. All-organic aqueous batteries consisting of quinone-hydroquinone derivatives with proton/aluminum-ion co-insertion mechanism[J]. Applied Surface Science, 2023, 625: 157174.

131. Xue J, Su Y, Liu A, et al. Interfacial Modification of Multifunctional Organic Ammonium Salt for PEDOT: PSS‐based Inverted Perovskite Solar Cells[J]. Energy Technology, 2023.

130. Lu Y, Wang X, Kang Q, et al. Robust lamellar Fe2O3@ SnO2 heterostructure for long cycling and high-rate lithium storage[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 669: 131481.

129. Ye X, Liu A, Gao L, et al. Computational screening of Cs based vacancy‐ordered double perovskites for solar cell and photocatalysis applications[J]. EcoMat, 2023, 5(3): e12295.

128. Li L, Zeng K, He Z, et al. Synergistic Photothermal Effect of the Wood‐SnS‐AgNPs for Efficient Solar‐Driven Steam Generation[J]. Energy Technology, 2023: 2201284.

127. Chen Y, Zhao Y, Liu H, et al. Crab Shell-Derived SnS2/C and FeS2/C Carbon Composites as Anodes for High-Performance Sodium-Ion Batteries[J]. ACS omega, 2023, 8(10): 9145-9153.

126. Huang H, Kang Q, Chen H, et al. Synthesis of one-dimensional vanadium-doped Co@ CNT for highly efficient methanol oxidation reaction by oxygen vacancies engineering[J]. Materials Letters, 2023, 333: 133555.

125. Wang X, Wang R, Kang Q, et al. Construction of Cu-doped Co3O4/rGO composites with a typical buffer structure for high-performance lithium storage[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 656: 130325.

124. Chen Z, Zhou A, Lin S, et al. Photothermal CO-PROX reaction over ternary CuCoMnO x spinel oxide catalysts: the effect of the copper dopant and thermal treatment[J]. Physical Chemistry Chemical Physics, 2023, 25(11): 8064-8073.

123. Gao L, He Z, Xu C, et al. Systematic investigation of metal dopants and mechanism for the SnO 2 electron transport layer in perovskite solar cells[J]. Physical Chemistry Chemical Physics, 2023, 25(10): 7229-7238.

122. Yin Z, Liu X, Chen S, et al. Interface engineering and anion engineering of Mo‐based heterogeneous electrocatalysts for hydrogen evolution reaction. Energy & Environmental Materials, 2023, 6(1): e12310.

121. Chen Y, Jiang B, Zhao Y, et al. Diatomite and Glucose Bioresources Jointly Synthesizing Anode/Cathode Materials for Lithium-Ion Batteries[J]. Coatings, 2023, 13(1): 146.

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


2022

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

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

117. Synthesis of one-dimensional vanadium-doped Co@ CNT for highly efficient methanol oxidation reaction by oxygen vacancies engineering, H Huang, Q Kang, H Chen, H Yi, T Ma

Materials Letters, 2022: 133555

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

115. Molecular structure design and interface behavior of ionic liquids on metal surfaces: A theoretical study, W Guan, H Zhu, Y Zhang, X Ren, T Ma, A Liu, Surfaces and Interfaces 34(2022): 102314

114. Iodine Conversion Chemistry in Aqueous Batteries: Challenges, Strategies, and Perspectives,

L Yan, S Zhang, Q Kang, X Meng, Z Li, T Liu, T Ma, Z Lin, Energy Storage Materials, 54(2022): 339-365

113. SnOx as Bottom Hole Extraction Layer and Top In Situ Protection Layer Yields over 14% Efficiency in Sn-Based Perovskite Solar Cells, L Wang, M Chen, S Yang, N Uezono, Q Miao, G Kapil, AK Baranwal, T Ma, etal., ACS Energy Letters 7 (2022): 3703-3708

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

111. Simulated solar light-driven photothermal preferential oxidation of carbon monoxide in H2-rich streams over fast-synthesized CuCeO2–x nanorods, X Guo, W Ye, Z Chen, A Zhou, D Jin, T Ma, Applied Catalysis B: Environmental 310, 121334 1 2022

110. Highly efficient and stable perovskite solar cells induced by novel bulk organosulfur ammonium, Z He, C Xu, L Li, A Liu, T Ma, L Gao, Materials Today Energy 26(2022): 101004

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

108. Mechanism of oxygen reduction reaction on Ni/CNTs and Ni/X-CNTs (X= B, N, O) catalysts: a theoretical study, H Zhu, Y Yang, M Kong, X Ren, T Ma, A Liu, Theoretical Chemistry Accounts 141 (2022): 1-8

107. DFT study of X‐site ion substitution doping of Cs2PtX6 on its structural and electronic properties, X Ye, A Liu, Y Zhao, Q Han, T Kitamura, T Ma, International Journal of Energy Research 46 (2022): 8471-8479

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

105. Petal-like FexSy/WS2 Heterojunction Nanosheets as an Electrocatalyst for Highly Effective Hydrogen Evolution Reaction, H Chen, Y Li, H Huang, Q Kang, T Ma, Energy & Fuels 36(2022):  4888-4894

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

103. Two‐Dimensional MXene Supported Bismuth for Efficient Electrocatalytic Nitrogen Reduction,A Liu, X Liang, H Zhu, X Ren, L Gao, M Gao, Y Yang, G Li, T Ma, ChemCatChem 14 (2022):  e202101683

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

ChemCatChem 14(2022): e202101775

101. 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(2022): 100968

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

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

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

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

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

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

Materials Today Nano 17(2022): 100156

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

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

92. A Heat‐Liquefiable Solid Precursor for Ambient Growth of Perovskites with High Tunability, Performance and Stability, Y He, Z Lin, J Wang, K Zhang, X Xu, Y Li, X Huang, T Ma, S Xiao, S Yang, Small Methods, (2022): 2200384

91. Cascaded Bandgap Design for Highly Efficient Electron Transport Layer-Free Perovskite Solar Cells, L Gao, C Xu, Y Su, A Liu, T Ma, Chemical Communications, 58(2022):6749-6752

90. In Situ Growth of Bifunctional Modification Material for Highly Efficient Electron-Transport-Layer-Free Perovskite Solar Cells,L Gao, C Xu, Z He, Y Su, T Ma,New Journal of Chemistry,46(2022):12767-12772

89. MXenes and their composites for lithium-and sodium-ion battery applications,A Liu, X Liang, T Ma,Mxenes and their Composites,(2022):307-341

88. Current progress of metal sulfides derived from metal organic frameworks for advanced electrocatalysis: potential electrocatalysts with diverse applications,X Liu, Y Li, Z Cao, Z Yin, T Ma, S Chen,Journal of Materials Chemistry A,10(2022):1617-1641

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

86. Guo X, Ye W, Chen Z, et al. Simulated Solar Light-driven Photothermal Preferential Oxidation of Carbon Monoxide in H2-rich Streams over Fast-synthesized CuCeO2-x Nanorods[J]. Applied Catalysis B: Environmental, 310(2022)121334.

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

84. L. Sun, C. Zhang, L. Yan, L. Gao, T. Ma, Praseodymium-doped triple-cation perovskite layer for enhanced photovoltaic performance, Journal of Solid State Chemistry, 307 (2022) 122826.

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


2021

82.   K. Liu, C. Li, L. Yan, M. Fan, Y. Wu, X. Meng*, T. Ma*, MOFs and their derivatives as Sn-based anode materials for lithium/sodium ion batteries, Journal of Materials Chemistry A, 9 (2021) 27234-27251.

81.   Zhou, Y.;  Liu, C. Y.;  Meng, F. N.;  Zhang, C.;  Wei, G. Y.;  Gao, L. G.; Ma, T. L., Recent Progress in Perovskite Solar Cells Modified by Sulfur Compounds. Solar Rrl 2021, 5 (4).

80.   Yan, L. J.;  Zeng, X. M.;  Zhao, S.;  Jiang, W.;  Li, Z. H.;  Gao, X. H.;  Liu, T. F.;  Ji, Z. K.;  Ma, T. L.;  Ling, M.; Liang, C. D., 9,10-Anthraquinone/K2CuFe(CN)(6): A Highly Compatible Aqueous Aluminum-Ion Full-Battery Configuration. Acs Applied Materials & Interfaces 2021, 13 (7), 8353-8360.

79.   Liu, A. M.;  Yang, Y. N.;  Ren, X. F.;  Gao, M. F.;  Liang, X. Y.; Ma, T. L., A peanut shell-derived economical and eco-friendly biochar catalyst for electrochemical ammonia synthesis under ambient conditions: combined experimental and theoretical study. Catalysis Science & Technology 2021, 11 (4), 1526-1536.

78.   Liu, A. M.;  Yang, Y. N.;  Kong, D. Z.;  Ren, X. F.;  Gao, M. F.;  Liang, X. Y.;  Yang, Q. Y.;  Zhang, J. L.;  Gao, L. G.; Ma, T. L., DFT study of the defective carbon materials with vacancy and heteroatom as catalyst for NRR. Applied Surface Science 2021, 536.

77.   Liu, A. M.;  Yang, Y. A.;  Shi, D. J.;  Ren, X. F.; Ma, T. L., Theoretical study of the mechanism of methanol oxidation on PtNi catalyst. Inorganic Chemistry Communications 2021, 123.

76.   Liu, A. M.;  Liang, X. Y.;  Yang, Q. Y.;  Ren, X. F.;  Gao, M. F.;  Yang, Y. N.; Ma, T. L., Electrocatalytic Synthesis of Ammonia Using a 2D Ti3C2 MXene Loaded with Copper Nanoparticles. Chempluschem 2021, 86 (1), 166-170.

75.   Liu, A. M.;  Guan, W. X.;  Zhao, X. D.;  Ren, X. F.;  Liang, X. Y.;  Gao, L. G.;  Li, Y. Q.; Ma, T. L., Investigation on the interfacial behavior of polyorganic inhibitors on a metal surface by DFT study and MD simulation. Applied Surface Science 2021, 541.

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

73.   Liu, A. M.;  Gao, M. F.;  Ma, Y.;  Ren, X. F.;  Gao, L. G.;  Li, Y. Q.; Ma, T. L., Theoretical study of the influence of doped oxygen group elements on the properties of organic semiconductors. Nanoscale Advances 2021.

72.   Liang, X. Y.;  Ren, X. F.;  Yang, S. Z.;  Liu, L. Z.;  Xiong, W.;  Cheng, L.;  Ma, T. L.; Liu, A. M., Theoretical study of the influence of doped niobium on the electronic properties of CsPbBr3. Nanoscale Advances 2021, 3 (7), 1910-1916.

71.   Liang, X. Y.;  Ren, X. F.;  Yang, Q. Y.;  Gao, L. G.;  Gao, M. F.;  Yang, Y. A.;  Zhu, H. D.;  Li, G. X.;  Ma, T. L.; Liu, A. M., A two-dimensional MXene-supported metal-organic framework for highly selective ambient electrocatalytic nitrogen reduction. Nanoscale 2021, 13 (5), 2843-2848.

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

69.   Li, Y. Q.;  Yin, Z. H.;  Cui, M.;  Liu, X.;  Xiong, J. B.;  Chen, S. R.; Ma, T. L., Interface engineering of transitional metal sulfide-MoS2 heterostructure composites as effective electrocatalysts for water-splitting. Journal of Materials Chemistry A 2021, 9 (4), 2070-2092.

68.   Han, Q. J.;  Yang, S. Z.;  Wang, L.;  Yu, F. Y.;  Zhang, C.;  Wu, M. X.; Ma, T. L., The sulfur-rich small molecule boosts the efficiency of carbon-based CsPbI2Br perovskite solar cells to approaching 14%. Solar Energy 2021, 216, 351-357.


2020

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

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

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

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

63.   Yu, F. Y.;  Wang, L.;  Ren, K. K.;  Yang, S. Z.;  Xu, Z. H.;  Han, Q. J.; Ma, T. L., Cs-Incorporated AgBiI4 Rudorffite for Efficient and Stable Solar Cells. Acs Sustainable Chemistry & Engineering 2020, 8 (27), 9980-9987.

62.   Yang, S. Z.;  Wang, L.;  Zhao, S.;  Liu, A. M.;  Zhou, Y.;  Han, Q. J.;  Yu, F. Y.;  Gao, L. G.;  Zhang, C.; Ma, T. L., Novel Lead-Free Material Cs2PtI6 with Narrow Bandgap and Ultra-Stability for Its Photovoltaic Application. Acs Applied Materials & Interfaces 2020, 12 (40), 44700-44709.

61.   Yang, S. Z.;  Wang, L.;  Gao, L. G.;  Cao, J. M.;  Han, Q. J.;  Yu, F. Y.;  Kamata, Y.;  Zhang, C.;  Fan, M. Q.;  Wei, G. Y.; Ma, T. L., Excellent Moisture Stability and Efficiency of Inverted All-Inorganic CsPbIBr2 Perovskite Solar Cells through Molecule Interface Engineering. Acs Applied Materials & Interfaces 2020, 12 (12), 13931-13940.

60.   Xu, Z. H.;  Zhang, C.;  Yu, F. Y.;  Kamata, Y.;  Hayase, S.; Ma, T. L., Synthesis of Sb(V) Complexes with Pyridyl Cations and Application for Lead-free Perovskite Solar Cells. Chemistry Letters 2020, 49 (8), 944-946.

59.   Xu, Z. H.;  Wang, L.;  Han, Q. J.;  Kamata, Y.; Ma, T. L., Suppression of Iodide Ion Migration via Sb2S3 Interfacial Modification for Stable Inorganic Perovskite Solar Cells. Acs Applied Materials & Interfaces 2020, 12 (11), 12867-12873.

58.   Wu, M. X.;  Sun, M. Y.;  Zhou, H. W.;  Ma, J. Y.; Ma, T. L., Carbon Counter Electrodes in Dye-Sensitized and Perovskite Solar Cells. Advanced Functional Materials 2020, 30 (7).

57.   Wang, N.;  Hu, J. J.;  Gao, L. G.; Ma, T. L., Current Progress in Solid-State Electrolytes for Dye-Sensitized Solar Cells: A Mini-Review. Journal of Electronic Materials 2020, 49 (12), 7085-7097.

56.   Wang, L.;  Yang, S. Z.;  Han, Q. J.;  Yu, F. Y.;  Cai, X. Y.;  Liu, F. J.;  Zhang, C.; Ma, T. L., Bifunctional Organic Disulfide for High-Efficiency and High-Stability Planar Perovskite Solar Cells. Acs Applied Energy Materials 2020, 3 (10), 9724-9731.

55.   Nam, K. S.;  Krishnamurthy, S.;  Qing, S.;  Toyoda, T.;  Yoshino, K.;  Minemoto, T.;  Ma, T. L.;  Pandey, S.; Hayase, S., Stability Improvement of Perovskite Solar Cells by Adding Sb-Xanthate to Precursor Solution. Physica Status Solidi a-Applications and Materials Science 2020, 217 (18).

54.   Meng, F. N.;  Liu, C. Y.;  Gao, L. G.; Ma, T. L., Strategies for Interfacial Modification in Perovskite Solar Cells. Progress in Chemistry 2020, 32 (6), 817-835.

53.   Meng, F. N.;  Li, Y.;  Gao, L. G.;  Liu, A. M.;  Li, Y. Q.;  Wang, T. H.;  Zhang, C.;  Fan, M. Q.;  Wei, G. Y.; Ma, T. L., Intermediate-Controlled Interfacial Engineering for Stable and Highly Efficient Carbon-Based PSCs. Acs Applied Materials & Interfaces 2020, 12 (30), 34479-34486.

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

51.   Liu, A. M.;  Yang, Y. N.;  Ren, X. F.;  Zhao, Q. D.;  Gao, M. F.;  Guan, W. X.;  Meng, F. N.;  Gao, L. G.;  Yang, Q. Y.;  Liang, X. Y.; Ma, T. L., Current Progress of Electrocatalysts for Ammonia Synthesis Through Electrochemical Nitrogen Reduction Under Ambient Conditions. Chemsuschem 2020, 13 (15), 3766-3788.

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

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

48.   Liu, A. M.;  Liang, X. Y.;  Yang, Q. Y.;  Ren, X. F.;  Gao, M. F.;  Yang, Y. A.; Ma, T. L., Metal-Organic-Framework-Derived Cobalt-Doped Carbon Material for Electrochemical Ammonia Synthesis under Ambient Conditions. Chemelectrochem 2020, 7 (24), 4900-4905.

47.   Liu, A. M.;  Liang, X. Y.;  Ren, X. F.;  Guan, W. X.;  Gao, M. F.;  Yang, Y. N.;  Yang, Q. Y.;  Gao, L. G.;  Li, Y. Q.; Ma, T. L., Recent Progress in MXene-Based Materials: Potential High-Performance Electrocatalysts. Advanced Functional Materials 2020, 30 (38).

46.   Liu, A. M.;  Li, C.;  Ren, X. F.;  Gao, L. G.; Ma, T. L., Co loaded on graphene with interfacial structure as high performance catalyst for 4e(-) ORR: a DFT study. Ionics 2020, 26 (7), 3483-3490.

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

44.   Liu, A. M.;  Gao, M. F.;  Ren, X. F.;  Meng, F. N.;  Yang, Y. N.;  Yang, Q. Y.;  Guan, W. X.;  Gao, L. G.;  Liang, X. Y.; Ma, T. L., A two-dimensional Ru@MXene catalyst for highly selective ambient electrocatalytic nitrogen reduction. Nanoscale 2020, 12 (20), 10933-10938.

43.   Liu, A. M.;  Gao, M. F.;  Ren, X. F.;  Meng, F. N.;  Yang, Y. N.;  Gao, L. G.;  Yang, Q. Y.; Ma, T. L., Current progress in electrocatalytic carbon dioxide reduction to fuels on heterogeneous catalysts. Journal of Materials Chemistry A 2020, 8 (7), 3541-3562.

42.   Liu, A. M.;  Gao, M. F.;  Gao, Y. C.;  Ren, X. F.;  Yang, Y. N.;  Yang, Q. Y.;  Li, Y. Q.;  Gao, L. G.;  Liang, X. Y.; Ma, T. L., DFT study of Ru/graphene as high-performance electrocatalyst for NRR. Inorganic Chemistry Communications 2020, 120.

41.   Li, Y. Q.;  Yin, Z. H.;  Cui, M.;  Chen, S. R.; Ma, T. L., Bimetallic cobalt molybdenum carbide-cobalt composites as superior bifunctional oxygen electrocatalysts for Zn-air batteries. Materials Today Energy 2020, 18.

40.   Li, Y. Q.;  Wang, C.;  Cui, M.;  Chen, S. R.;  Gao, L. G.;  Liu, A. M.; Ma, T. L., Facile synthesis of ZnS decorated N, S co-doped carbon polyhedron as high efficiency oxygen reduction reaction catalyst for Zn-air battery. Applied Surface Science 2020, 509.

39.   Li, Y. Q.;  Cui, M.;  Yin, Z. H.;  Chen, S. R.; Ma, T. L., Metal-organic framework based bifunctional oxygen electrocatalysts for rechargeable zinc-air batteries: current progress and prospects. Chemical Science 2020, 11 (43), 11646-11671.

38.   Hamada, K.;  Tanaka, R.;  Kamarudin, M. A.;  Shen, Q.;  Iikubo, S.;  Minemoto, T.;  Yoshino, K.;  Toyoda, T.;  Ma, T. L.;  Kang, D. W.; Hayase, S., 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. Acs Applied Materials & Interfaces 2020, 12 (15), 17788-17794.

37.   Guo, X. L.;  Ye, W. X.; Ma, T. L., Investigation of the re-dispersion of matrix Cu species in Cu(x)Ce(1-x)O(2)nanorod catalysts and its effect on the catalytic performance in CO-PROX. Catalysis Science & Technology 2020, 10 (14), 4766-4775.

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

35.   Gao, L. G.;  Yan, Y. L.;  Li, Y.; Ma, T. L., Comparison of Physical Isolation on Large Active Area Perovskite Solar Cells. Chemical Research in Chinese Universities 2020, 36 (6), 1279-1283.

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

33.   Gao, L. G.;  Liu, C. Y.;  Meng, F. N.;  Liu, A. M.;  Li, Y. Q.;  Li, Y.;  Zhang, C.;  Fan, M. Q.;  Wei, G. Y.; Ma, T. L., Significantly Enhanced V-oc and Efficiency in Perovskite Solar Cells through Composition Adjustment of SnS2 Electron Transport Layers. Acs Sustainable Chemistry & Engineering 2020, 8 (25), 9250-9256.

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

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

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


2019

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

28.   Zhang, P. T.;  Yang, F.;  Kapil, G.;  Ng, C. H.;  Ma, T. L.; Hayase, S., Preparation of Perovskite Films under Liquid Nitrogen Atmosphere for High Efficiency Perovskite Solar Cells. Acs Sustainable Chemistry & Engineering 2019, 7 (4), 3956-3961.

27.   Zhang, C.;  Teo, S.;  Guo, Z. L.;  Gao, L. G.;  Kamata, Y.;  Xu, Z. H.; Ma, T. L., Development of a Mixed Halide-chalcogenide Bismuth-based Perovskite MABiI(2)S with Small Bandgap and Wide Absorption Range. Chemistry Letters 2019, 48 (3), 249-252.

26.   Yang, S. Z.;  Guo, Z. L.;  Gao, L. G.;  Yu, F. Y.;  Zhang, C.;  Fan, M. Q.;  Wei, G. Y.; Ma, T. L., Bifunctional Dye Molecule in All-Inorganic CsPbIBr2 Perovskite Solar Cells with Efficiency Exceeding 10%. Solar Rrl 2019, 3 (9).

25.   Yang, F.;  Kamarudin, M. A.;  Hirotani, D.;  Zhang, P. T.;  Kapil, G.;  Ng, C. H.;  Ma, T. L.; Hayase, S., Melamine Hydroiodide Functionalized MAPbI(3) Perovskite with Enhanced Photovoltaic Performance and Stability in Ambient Atmosphere. Solar Rrl 2019, 3 (1).

24.   Yan, Y. L.;  Gao, J. M.;  Meng, F. N.;  Wang, N.;  Gao, L. G.; Ma, T. L., Large-Area Perovskite Solar Cells. Progress in Chemistry 2019, 31 (7), 1031-1043.

23.   Yan, Y.;  Hao, X. F.;  Gao, L. G.;  Lin, S. S.;  Cui, N.;  Li, Y. H.;  Hao, C.;  Ma, T. L.; Wang, H. X., Highly accessible hierarchical porous carbon from a bi-functional ionic liquid bulky gel: high-performance electrochemical double layer capacitors. Journal of Materials Chemistry A 2019, 7 (44), 25297-25304.

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

21.   Xu, Z. H.;  Teo, S. H.;  Gao, L. G.;  Guo, Z. L.;  Kamata, Y.;  Hayase, S.; Ma, T. L., La-doped SnO2 as ETL for efficient planar-structure hybrid perovskite solar cells. Organic Electronics 2019, 73, 62-68.

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

19.   Wang, Z.;  Baranwal, A. K.;  Kamarudin, M. A.;  Ng, C. H.;  Pandey, M.;  Ma, T. L.; Hayase, S., Xanthate-induced sulfur doped all-inorganic perovskite with superior phase stability and enhanced performance. Nano Energy 2019, 59, 258-267.

18.   Wang, Z.;  Baranwal, A. K.;  Kamarudin, M. A.;  Kamata, Y.;  Ng, C. H.;  Pandey, M.;  Ma, T. L.; Hayase, S., Structured crystallization for efficient all-inorganic perovskite solar cells with high phase stability. Journal of Materials Chemistry A 2019, 7 (35), 20390-20397.

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

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

15.   Meng, F. N.;  Liu, A. M.;  Gao, L. G.;  Cao, J. M.;  Yan, Y. L.;  Wang, N.;  Fan, M. Q.;  Wei, G. Y.; Ma, T. L., Current progress in interfacial engineering of carbon-based perovskite solar cells. Journal of Materials Chemistry A 2019, 7 (15), 8690-8699.

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

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

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

11.   Li, Y. Q.;  Huang, H. Y.;  Chen, S. R.;  Yu, X.;  Wang, C.; Ma, T. L., 2D nanoplate assembled nitrogen doped hollow carbon sphere decorated with Fe3O4 as an efficient electrocatalyst for oxygen reduction reaction and Zn-air batteries. Nano Research 2019, 12 (11), 2774-2780.

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

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

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

7.     Huang, X.;  Zhang, Z. G.;  Li, H.;  Wang, H. X.; Ma, T. L., In-situ growth of nanowire WO2.72 on carbon cloth as a binder-free electrode for flexible asymmetric supercapacitors with high performance. Journal of Energy Chemistry 2019, 29, 58-64.

6.     Huang, H. Y.;  Li, Y. Q.;  Wang, N.;  Chen, S. R.;  Wang, C.; Ma, T. L., Efficient oxygen reduction reaction catalyst derived from ZnO@ zeolite imidazolate framework nanowire composite. Inorganic Chemistry Communications 2019, 101, 23-26.

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

4.     Guo, Z. L.;  Zhao, S.;  Liu, A. M.;  Kamata, Y.;  Teo, S.;  Yang, S. Z.;  Xu, Z. H.;  Hayase, S.; Ma, T. L., Niobium Incorporation into CsPbI2Br for Stable and Efficient All-Inorganic Perovskite Solar Cells. Acs Applied Materials & Interfaces 2019, 11 (22), 19994-20003.

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

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

1.     Cao, J. M.;  Meng, F. N.;  Gao, L. G.;  Yang, S. Z.;  Yan, Y. L.;  Wang, N.;  Liu, A. M.;  Li, Y. Q.; Ma, T. L., Alternative electrodes for HTMs and noble-metal-free perovskite solar cells: 2D MXenes electrodes. Rsc Advances 2019, 9 (59), 34152-34157.