王朋
Professor
Visit:
Personal Information:
  • Name (Pinyin):
    WangPeng
  • E-Mail:
    pengwangicm@sdu.edu.cn
  • Date of Employment:
    2015-05-06
  • School/Department:
    State Key Lab of Crystal Materials, Shandong University
  • Education Level:
    With Certificate of Graduation for Doctorate Study
  • Business Address:
    410,Functional Crystal Building
  • Gender:
    Male
  • Contact Information:
    pengwangicm@sdu.edu.cn
  • Degree:
    Doctoral Degree in Engineering
  • Status:
    Employed
  • Alma Mater:
    Shandong University
  • Supervisor of Doctorate Candidates
  • Supervisor of Master's Candidates
Discipline:
Physical Chemistry;
Honors and Titles:

2014-03-14    National Excellent Doctoral Dissertation;
2016-02-26    Second Prize in Natural Science awarded by the Ministry of Education,The third listed participant;
2021-10-20    Shandong Province Excellent Master's Thesis Guidance Award;
2021-10-20    Shandong Province Excellent Doctoral Dissertation Guidance Award;
Biography

The research group has been consistently engaged in fundamental and applied research on "solar photocatalytic water splitting for green hydrogen production". Focusing on the critical bottleneck issues in solar energy conversion—such as the rapid recombination of photo-generated charge carriers and low efficiency in the solar energy conversion process, various new material systems have been designed, new strategies for promoting photo generated charge separation have been developed, and a series of innovative achievements have been made. In the past five years, as corresponding authors, over 50 research papers in internationally renowned journals, including Advanced Materials (Adv. Mater.), Angewandte Chemie International Edition (Angew. Chem. Int. Ed.), Energy & Environmental Science (Energy Environ. Sci.), Nature Communications (Nat. Commun.), Advanced Functional Materials (Adv. Funct. Mater.), and ACS Catalysis (ACS Catal.) have been published. Among these, 11 papers are ESI Highly Cited Papers, and 1 paper was featured as a cover article. More than 20 invention patents have been applied for and over 10 have been authorized. Up to now, SCI has been cited more than 10000 times. Principal Investigator (PI) was supported by the National Overseas High-Level Youth Talent Program (2015). Doctoral dissertation was selected as a National Outstanding Doctoral Dissertation (2013). Delivered over 20 keynote and invited presentations at domestic and international conferences. Currently serving as a Youth Editorial Board Member for Chinese Chemical Letters and a Guest Editor for journals such as Nanomaterials.


Education
  • 2005-9 — 2010-6
    Shandong University
    Material Science
    Doctoral Degree in Philosophy
  • 2001-9 — 2005-7
    QuFu Normal University
    Chemistry
    Bachelor's Degree
Publication
Papers

1. 徐亚洋. Dual-plasmon-enhanced nitrophenol hydrogenation over W<sub>18</sub>O<sub>49</sub>-Au heterostructures studied at the single-particle level .CATALYSIS SCIENCE & TECHNOLOGY .2023,13 (5):1301

2. 张雨佳. In Situ Monitoring of the Spatial Distribution of Oxygen Vacancies and Enhanced Photocatalytic Performance at the Single-Particle Level .Nano Letters.2023,23 (4):1244

3. 毛玉印. Asymmetric Cu(I)─W Dual-Atomic Sites Enable C─C Coupling for Selective Photocatalytic CO2 Reduction to C2H4 .Advanced Science.2024,11 (28):2401933

4. 孙斌. Complex-confinement strategy to high-loading and structure-tunable indium single-atom catalysts toward efficient electrocatalytic CO2 reduction .Chem Catalysis.2024,4 (2)

5. . Mesostructure-Specific Configuration of *CO Adsorption for Selective CO2 Electroreduction to C2+ Products .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2025

6. 刘洪利. Plasmon-Driven Highly Selective CO2 Photoreduction to C2H4 on Ionic Liquid-Mediated Copper Nanowires .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2024

7. . Composite of mixed-cation perovskite MA1-xFAxPbI3 with MoSe2 for enhanced photocatalytic H2 evolution .Chemical Engineering Journal.2025,511

8. . A scalable solar-driven photocatalytic system for separated H2 and O2 production from water .自然通讯.2025,16 (1)

9. 李雪. Space-confined growth of halide perovskite nanocrystals for enhanced photocatalytic hydrogen evolution .MOLECULAR CATALYSIS.2025,578

10. 孙斌. Unveiling pH-Dependent Adsorption Strength of *CO2? Intermediate over High-Density Sn Single Atom Catalyst for Acidic CO2-to-HCOOH Electroreduction .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2024

11. . Visible-Light-Driven Highly Selective 5-Hydroxymethylfurfural Upgrading and H2 Generation via Atomically Dispersed Ni Sites on ZnIn2S4 Nanosheets .ACS Catal. .2024

12. 谭鑫颖. Single Cobalt Atoms Induced Molecular O2 Activation for Enhanced Photocatalytic Biomass Upgrading on ZnIn2S4 Nanosheets .ACS Catal. .2023,13 (21):14395-14403

13. 张倩倩. Composite of formamidinium lead bromide perovskite FAPbBr3 with reduced graphene oxide (rGO) for efficient H2 evolution from HBr splitting .Journal of Colloid and interface science.2024,664

14. 雷龙飞. Strong Second-Harmonic Generation Induced by a Triphenylamine Based Bismuth?Organic Framework for Photocatalytic Activity Enhancement .ACS Applied Materials & Interfaces.2024,16 (16)

15. 高玉刚. Revealing the Lattice Carbonate Mediated Mechanism in Cu2(OH)2CO3 for Electrocatalytic Reduction of CO2 to C2H4 .Advanced Science.2024

16. 徐显斌. Pd-Decorated Cu2O-Ag Catalyst Promoting CO2 Electroreduction to C2H4 by Optimizing CO Intermediate Adsorption and Hydrogenation .ACS Applied Materials & Interfaces.2024,16 (13):16243-16252

17. 张明晖. Promoting Photocatalytic CO2 Methanation by the Construction of Cooperative Copper Dual-Active Sites .ACS Catal. .2024 :5275-5285

18. 赵爽. Fabrication of BiVO4 submicron rods photoanodes through phase transition assisted by Mo doping .CrystEngComm.2024

19. 王肇祺. An Efficient Bias-Free Si Photocathode Coupled BiVO4-Triethanolamine Photoelectrochemical Fuel Cell for Simultaneous Pollutant Treatment and Hydrogen Production .Advanced Functional Materials.2023

20. 黄慧宁. Bi20TiO32 Nanoparticles Doped with Yb3+ and Er3+ as UV, Visible, and Near-Infrared Responsive Photocatalysts .ACS Applied Nano Materials.2019,2 (9):5381-5388

21. 何玉杰. Photoelectrochemical Oxidation of Amines to Imines and Production of Hydrogen through Mo-Doped BiVO4Photoanode .ACS Omega.2022,7 (15):12816-12824

22. 鲍晓磊. Nitrogen vacancy enhanced photocatalytic selective oxidation of benzyl alcohol in g-C3N4 .International journal of hydrogen energy.2021,46 (76):37782-37791

23. 郑立仁. Fabrication of ZnO Ceramics with Defects by Spark Plasma Sintering Method and Investigations of Their Photoelectrochemical Properties .Nanomaterials .2021,11 (10)

24. 郑立仁. BiVO4 Ceramic Photoanode with Enhanced Photoelectrochemical Stability .Nanomaterials .2021,11 (9)

25. 张洪刚. Enhanced Charge Transfer Process and Photocatalytic Activity over a Phosphonate-based MOF via Amorphization Strategy .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2024

26. 翟广耀. Light-promoted CO2conversion from epoxides to cyclic carbonates at ambient conditions over a Bi-based metal-organic framework .ACS Catal. .2021,11 (4):1988-1994

27. 雷龙飞. Extended Light Absorption and Improved Charge Separation by Protonation of the Organic Ligand in a Bismuth-Based Metal-Organic Framework .chemistry-a European journal.2023

28. 林令统. Enhanced thermal assisted photocatalysis reduction of carbon dioxide over a Fe<sub>2-<i>x</i></sub>Ga<i><sub>x</sub></i>O<sub>3</sub> solid solution .CATALYSIS SCIENCE & TECHNOLOGY .2023,13 (12):3638

29. 李昱杰. In-situ growth of Ti3C2@MIL-NH2 composite for highly enhanced photocatalytic H2 evolution .Chemical Engineering Journal.2021,411

30. 周鹏. Tailoring the composition and structure of Ni3S2 by introduction of Co towards high efficiency energy storage device .Chemical Engineering Journal.2021,403

31. 郭昱昊. Multi-strategy preparation of BiVO<sub>4</sub> photoanode with abundant oxygen vacancies for efficient water oxidation .applied surface science.2023,614

32. 崔子浩. Composite of lead-free halide perovskite Cs3Bi2Br9 with TiO2 as an efficient photocatalyst for C(sp3)-H bond activation .应用催化-B.2023,333

33. 殷立文. Lead-Free Perovskite Cs<sub>2</sub>SnBr<sub>6</sub>/rGO Composite for Photocatalytic Selective Oxidation of 5-Hydroxymethylfurfural to 2,5-Diformylfuran .Chemistry-A European Journal.2023,29 (39)

34. 毛玉印. Electronic Structure Manipulation via Site-Selective Atomically Dispersed Ni for Efficient Photocatalytic CO2 Reduction .ACS Catal. .2023 :8362-8371

35. Xu, Kai. Spectroscopic investigation of the structural transformation of Ru in the Ru/CeO2 catalyst .CATALYSIS SCIENCE & TECHNOLOGY.2023,13 (21):6254-6263

36. 肖涤非. Stabilizing Cu2O for enhancing selectivity of CO2 electroreduction to C2H4 with the modification of Pd nanoparticles .Chemical Engineering Journal.2023,452

37. 张明晖. Coupling Benzylamine Oxidation with CO2 Photoconversion to Ethanol over a Black Phosphorus and Bismuth Tungstate S-Scheme Heterojunction .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2023,62 (36)

38. 王肇祺. Insight into the complexation mechanism between a BiVO<sub>4</sub> photoanode and tartaric acid for efficient photoelectrochemical H<sub>2</sub> production .Inorganic Chemistry Frontiers.2023,10 (16):4725

39. 秦学森. Growth mechanism of [100]-oriented TaON film through an endotaxial transformation from a (012)-LiTaO<sub>3</sub> single crystal substrate .CRYSTENGCOMM.2023,25 (19):2897

40. 肖涤非. Boosting the Electrochemical 5-Hydroxymethylfurfural Oxidation by Balancing the Competitive Adsorption of Organic and OH<SUP>-</SUP> over Controllable Reconstructed Ni<sub>3</sub>S<sub>2</sub>/NiO<sub>x</sub> .ADVANCED MATERIALS .2023

41. 张海鹏. Fabrication of Hematite Photoanode Consisting of (110)-Oriented Single Crystals .ChemSusChem.2023

42. 吴亚强. An organometal halide perovskite supported Pt single-atom photocatalyst for H-2 evolution .Energy and Environmental Science.2022,15 (3):1271

43. . In Situ Preparation of CsPbBr 3 @CsPb 2 Br 5 Composite Assisted with Water as a Highly Efficient and Stable Catalyst for Photothermal CO 2 Hydrogenation .Chemistry-A European Journal.2022 (n/a)

44. 李鑫. Self-assembled supramolecular system PDINH on TiO2 surface enhances hydrogen production .胶体与界面.2018 (525):136

45. 张雨佳. In Situ Monitoring of the Spatial Distribution of Oxygen Vacancies and Enhanced Photocatalytic Performance at the Single-Particle Level .Nano Letters.2023 (23):1244

46. . Synthesis of a WO3 photocatalyst with high photocatalytic activity and stability using synergetic internal Fe3+ doping and superficial Pt loading for ethylene degradation under visiblelight irradiation .Catalysis Science and Technology.2018 (9)

47. . Composite of lead-free halide perovskite Cs3Bi2Br9 with TiO2 as an efficient photocatalyst for C(sp3)?? H bond activation .应用催化-B.2023 (333):122812

48. 李蓓. In Situ Monitoring Charge Transfer on Topotactic Epitaxial Heterointerface for Tetracycline Degradation at the Single-Particle Level .ACS Catal. .2022

49. 徐亚洋. Strain-assisted in-situ formed oxygen defective WO3 film for photothermal-synergistic reverse water gas shift reaction and single-particle study .Chemical Engineering Journal.2022,433

50. 吕敏. BiVO4 quadrangular nanoprisms with highly exposed {101} facets for selective photocatalytic oxidation of benzylamine .Journal of Materials Chemistry A.2022

51. 刘木. Enhanced stability and activity towards photocatalytic CO2 reduction via supercycle ALD of Cu and TiO2 .Chemical Engineering Journal.2022,429

52. 马法豪. Targeted Regulation of the Electronic States of Nickel Toward the Efficient Electrosynthesis of Benzonitrile and Hydrogen Production .ACS Applied Materials & Interfaces.2021,13 (47):56140

53. 仝凤霞. Probing the Mechanism of Plasmon-Enhanced Ammonia Borane Methanolysis on a CuAg Alloy at a Single-Particle Level .Acs catalysis.2021,11 (17):10814

54. 赵云瑞. Borate-modulated amorphous NiFeB nanocatalysts as highly active and stable electrocatalysts for oxygen evolution reaction .JOURNAL OF ALLOYS AND COMPOUNDS .2022,903

55. 仝凤霞. Plasmon-Enhanced Water Activation for Hydrogen Evolution from Ammonia-Borane Studied at a Single-Particle Level .Acs catalysis.2022,12 (6):3558

56. 宫雪芹. Photoreforming of plastic waste poly (ethylene terephthalate) via in-situ derived CN-CNTs-NiMo hybrids .应用催化B.2022,307

57. 仝凤霞. Boosting hot electrons transfer via laser-induced atomic redistribution for plasmon-enhanced nitroreduction and single-particle study .Journal of Catalysis.2022,407 :115

58. 刘福燕. alpha-Fe2O3 Film with Highly Photoactivity for Non-Enzymatic Photoelectrochemical Detection of Glucose .ELECTROANALYSIS Journal.2019,31 (9):1809

59. 开爽爽. An innovative Au-CdS/ZnS-RGO architecture for efficient photocatalytic hydrogen evolution .Journal of Materials Chemistry A.2018 (7)

60. 李昱杰. Boron containing metal–organic framework for highly selective photocatalytic production of H2O2 by promoting two-electron O2 reduction .MATERIALS HORIZONS.2021 (8):2842

61. . Boosting the electrocatalytic HER performance of Ni3N-V2O3 via the interface coupling effect .Applied Catalysis B: Environmental.2020 (283):119590

62. 雷龙飞. A Bismuth-Based Metal?Organic Framework for Visible-LightDriven Photocatalytic Decolorization of Dyes and Oxidation of Phenylboronic Acids .Inorg. Chem. .2022 (61):11110

63. 翟广耀. Improved photocatalytic CO2 and epoxides cycloaddition via the synergistic effect of Lewis acidity and charge separation over Zn modified UiO-bpydc .Applied Catalysis B: Environmental.2021 (301):120793

64. 李昱杰. Synergistic effect between boron containing metal-organic frameworks and light leading to enhanced CO2 cycloaddition with epoxides .Chemical Engineering Journal.2022 (437):135363

65. . Oxygen Vacancies Enhanced Ozonation toward Phenol Derivatives Removal over Ov?Bi2O3 .ACS EST Water .2022 (2):1725

66. 张洪刚. Photo-induced photo-thermal synergy effect leading to efficient CO2 cycloaddition with epoxide over a Fe-based metal organic framework . JOURNAL OF COLLOID AND INTERFACE SCIENCE.2022 (625):33

67. 张庆燕. A biocompatible bismuth based metal-organic framework as efficient light-sensitive drug carrier . JOURNAL OF COLLOID AND INTERFACE SCIENCE.2022 (617):578

68. . Enhanced photocatalytic driven hydroxylation of phenylboric acid to phenol over pyrenetetrasulfonic acid intercalated ZnAl-LDHs . JOURNAL OF COLLOID AND INTERFACE SCIENCE.2021 (610):455

69. 翟广耀. Light-Promoted CO2 Conversion from Epoxides to Cyclic Carbonates at Ambient Conditions over a Bi-Based Metal?Organic Framework .Acs catalysis.2021 (11):1988

70. 邢丹宁. Two-dimensional π–d conjugated metal–organic framework Fe3(hexaiminotriphenylene)2 as a photo-Fenton like catalyst for highly efficient degradation of antibiotics .Applied Catalysis B: Environmenta.2021 (290):120029

71. 周鹏. Host dependent electrocatalytic hydrogen evolution of Ni/TiO2 composites .J. Mater. Chem. A..2021 (9):6325

72. 司圣和. Low-Coordination Single Au Atoms on Ultrathin ZnIn2S4 Nanosheets for Selective Photocatalytic CO2 Reduction towards CH4 .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2022,61 (41):202209446

73. 李在琪. In-situ-derived self-selective electrocatalysts for solar formate production from simultaneous CO2 reduction and methanol oxidation .Cell Reports Physical Science.2022,3 (7):100972

74. 李在琪. Electron-Rich Bi Nanosheets Promote CO2?- Formation for High-Performance and pH-Universal Electrocatalytic CO2 Reduction .ANGEWANDTE CHEMIE-INTERNATIONAL EDITION.2023,62 (11):202217569

75. 孟晓. Enabling unassisted solar water splitting with concurrent high efficiency and stability by robust earth-abundant bifunctional electrocatalysts .Nano Energy.2023 (0)

76. 姜为易. Stress-induced BiVO4 photoanode for enhanced photoelectrochemical performance .2022,304

77. 高玉刚. Promoting Electrocatalytic Reduction of CO2 to C2H4 Production by Inhibiting C2H5OH Desorption from Cu2O/C Composite .small.2022,18 (9):e2105212

78. 李继煜. NiCoP-CeO2 composites for efficient electrochemical oxygen evolution .RSC advances.2022,12 (22):13639-13644

79. 毛玉印. An integrated Si photocathode with lithiation-activated molybdenum oxide nanosheets for efficient ammonia synthesis .Nano Energy.2022,102 (11):107639

80. 司圣和. Low-Coordination Single Au Atoms on Ultrathin ZnIn2S4 Nanosheets for Selective Photocatalytic CO2 Reduction towards CH4 .2022

81. 李在琪. In-situ-derived self-selective electrocatalysts for solar formate production from simultaneous CO2 reduction and methanol oxidation .2022,3 (7)

82. 王肇祺. Boosting H2 Production from a BiVO4 Photoelectrochemical Biomass Fuel Cell by the Construction of a Bridge for Charge and Energy Transfer .ADVANCED MATERIALS.2022 :e2201594

83. 鲍晓磊. Photocatalytic Selective Oxidation of HMF Coupled with H2Evolution on Flexible Ultrathin g-C3N4Nanosheets with Enhanced N-H Interaction .ACS Catal. .2022,12 (3):1919-1929

84. 鲍晓磊. Molten-salt assisted synthesis of Cu clusters modified TiO2 with oxygen vacancies for efficient photocatalytic reduction of CO2 to CO .Chemical Engineering Journal.2022,445

85. 高玉刚. Promoting Electrocatalytic Reduction of CO2 to C2H4 Production by Inhibiting C2H5OH Desorption from Cu2O/C Composite .Small.2022,18 (9)

86. 姜为易. <p>Stress-induced BiVO(4 )photoanode for enhanced photoelectrochemical performance</p> .应用催化B.2022,304

87. 李继煜. NiCoP-CeO2 composites for efficient electrochemical oxygen evolution .RSC ADVANCES.2022,12 (22):13639

88. 张彩云. Growth of bulk BiOBr single crystals for the characterization of intrinsic semi-conductive properties and application in ultraviolet photodetectors .Journal of Materials Chemistry C.2022,10 (28):10330-10337

89. 鲍晓磊. TiO2/Ti3C2 as an efficient photocatalyst for selective oxidation of benzyl alcohol to benzaldehyde .应用催化-b.2021,286

90. 任茜茜. Oxygen vacancy enhancing CO2 electrochemical reduction to CO on Ce-doped ZnO catalysts .SURFACES AND INTERFACES.2021,23

91. 崔子浩. In situ integration of Fe3N@Co4N@CoFe alloy nanoparticles as efficient and stable electrocatalyst for overall water splitting .ELECTROCHIMICA ACTA.2021,395

92. 王敏瑞. Enhancing the Photoelectrochemical Water Oxidation Reaction of BiVO4 Photoanode by Employing Carbon Spheres as Electron Reservoirs .ACS catalysis.2020,10 (21):13031

93. 邢丹宁. Atomically dispersed cobalt-based species anchored on polythiophene as an efficient electrocatalyst for oxygen evolution reaction .Applied surface science.2021,545

94. 孙聪. Self-assembled g-C3N4 nanotubes/graphdiyne composite with enhanced photocatalytic CO2 reduction .JOURNAL OF ALLOYS AND COMPOUNDS .2021,868

95. 邢丹宁. Two-dimensional pi-d conjugated metal-organic framework Fe-3(hexaiminotriphenylene)(2) as a photo-Fenton like catalyst for highly efficient degradation of antibiotics .应用催化-b.2021,290

96. 李昱杰. In-situ growth of Ti3C2@MIL-NH2 composite for highly enhanced photocatalytic H-2 evolution .Chemical Engineering Journal.2021,411

97. 周鹏. Boosting the electrocatalytic HER performance of Ni3N-V2O3 via the interface coupling effect .应用催化-b.2021,283

98. 李昱杰. 2D/2D heterostructure of ultrathin BiVO4/Ti3C2 nanosheets for photocatalytic overall Water splitting .应用催化-b.2021,285

99. 周鹏. Host dependent electrocatalytic hydrogen evolution of Ni/TiO2 composites .Journal of Materials Chemistry A.2021,9 (10):6325

100. 王佳佳. Photostable Ag(I)-Based Metal-Organic Framework: Synthesis, Structure, and Photocatalytic Selective Oxidation Properties .Inorganic chenistry.2020,59 (22):16127

101. 翟广耀. Light-Promoted CO2 Conversion from Epoxides to Cyclic Carbonates at Ambient Conditions over a Bi-Based Metal-Organic Framework .ACS catalysis.2021,11 (4):1988

102. 赵仁娜. Li-intercalation boosted oxygen vacancies enable efficient electrochemical nitrogen reduction on ultrathin TiO2 nanosheets .Chemical Engineering Journal .2022,430

103. 姜为易. Free-Standing Nanoarrays with Energetic Electrons and Active Sites for Efficient Plasmon-Driven Ammonia Synthesis .Small .2022 (19)

104. 开爽爽. An innovative Au-CdS/ZnS-RGO architecture for efficient photocatalytic hydrogen evolution .Journal of Materials Chemistry A.2018,6 (7):2895

105. 仝凤霞. Plasmon-Mediated Nitrobenzene Hydrogenation with Formate as the Hydrogen Donor Studied at a Single-Particle Level .ACS catalysis.2021,11 (7):3801

106. 马法豪. Surface Fluorination Engineering of NiFe Prussian Blue Analogue Derivatives for Highly Efficient Oxygen Evolution Reaction .ACS Applied Materials & Interfaces.2021,13 (4):5142

107. 刘木. Substrate-dependent ALD of Cu-x on TiO2 and its performance in photocatalytic CO2 reduction .Chemical Engineering Journal .2021,405

108. 何祥韵. Photo-enhanced CO2 hydrogenation by plasmonic Cu/ZnO at atmospheric pressure .journal of solid state chemistry.2021,298

109. 刘小磊. Improving the HER activity of Ni3FeN to convert the superior OER electrocatalyst to an efficient bifunctional electrocatalyst for overall water splitting by doping with molybdenum .ELECTROCHIMICA ACTA.2020,333

110. 翟慧珊. ZnO nanorod decorated by Au-Ag alloy with greatly increased activity for photocatalytic ethylene oxidation .CHINESE JOURNAL OF CATALYSIS Journal.2020,41 (10):1613

111. 梁希壮. Design and synthesis of porous M-ZnO/CeO2 microspheres as efficient plasmonic photocatalysts for nonpolar gaseous molecules oxidation: Insight into the role of oxygen vacancy defects and M = Ag, Au nanoparticles .应用催化-b.2020,260

112. 梁希壮. Bias-Free Solar Water Splitting by Tetragonal Zircon BiVO4 Nanocrystal Photocathode and Monoclinic Scheelite BiVO4 Nanoporous Photoanode .Advanced functional materials.2020

113. 李鑫. ZnGeP2: A near-infrared-activated photocatalyst for hydrogen production .FRONTIERS OF PHYSICS.2020,15 (2)

114. 刘小磊. The synergy of thermal exfoliation and phosphorus doping in g-C3N4 for improved photocatalytic H-2 generation .International journal of hydrogen energy.2021,46 (5):3595

115. 刘小磊. Synthesis of Synergistic Nitrogen-Doped NiMoO4/Ni3N Heterostructure for Implementation of an Efficient Alkaline Electrocatalytic Hydrogen Evolution Reaction .ACS Appl. Energy Mater. .2020,3 (3):2440

116. 刘小磊. Research progress and surface/interfacial regulation methods for electrophotocatalytic hydrogen production from water splitting .MATERIALS TODAY ENERGY.2020,18

117. 朱相林. Fabrication of large size nanoporous BiVO4 photoanode by a printing-like method for efficient solar water splitting application .Ctalysis today.2020,340 :145

118. 崔子浩. ZnO nanorods modified with noble metal-free Co3O4 nanoparticles as a photocatalyst for efficient ethylene degradation under light irradiation .Catal. Sci. Technol. .2019,9 (21):6191

119. 仝凤霞. Plasmon-induced dehydrogenation of formic acid on Pd-dotted Ag@Au hexagonal nanoplates and single-particle study .应用催化-b.2020,277

120. 马法豪. Ni3B as a highly efficient and selective catalyst for the electrosynthesis of hydrogen peroxide .应用催化-b.2020,279

121. 王丛. Molybdenum Nitride Electrocatalysts for Hydrogen Evolution More Efficient than Platinum/Carbon: Mo2N/CeO2@Nickel Foam .ACS Applied Materials & Interfaces.2020,12 (26):29153

122. 高玉刚. Cu2O Nanoparticles with Both {100} and {111} Facets for Enhancing the Selectivity and Activity of CO2 Electroreduction to Ethylene .ADVANCED SCIENCE.2020,7 (6)

123. 马法豪. One-step synthesis of Co-doped 1T-MoS2 nanosheets with efficient and stable HER activity in alkaline solutions .MATERIALS CHEMISTRY AND PHYSICS Journal.2020,244

124. 李慧亮. In situ extract nucleate sites for the growth of free-standing carbon nitride films on various substrates .Ctalysis today.2020,340 :92

125. 王丛. Vanadium Nitride/Porous Carbon Composites on Ni Foam for High-Performance Supercapacitance .ChemistrySelect.2019,4 (37):11189

126. 梁忠. Electrodeposition of NiFe layered double hydroxide on Ni3S2 nanosheets for efficient electrocatalytic water oxidation .International journal of hydrogen energy.2020,45 (15):8659

127. 陈国强. Lead-Free Halide Perovskite Cs3Bi2xSb2-2xI9(x approximate to 0.3) Possessing the Photocatalytic Activity for Hydrogen Evolution Comparable to that of (CH3NH3)PbI3 .ADVANCED MATERIALS .2020,32 (39)

128. 王佳佳. Oxygen-Vacancy-Enhanced Singlet Oxygen Production for Selective Photocatalytic Oxidation .ChemSusChem.2020,13 (13):3488

129. 王敏瑞. Enhancing the Photoelectrochemical Water Oxidation Reaction of BiVO4 Photoanode by Employing Carbon Spheres as Electron Reservoirs .ACS Catalysis.2020,10 (21):13031

130. 周鹏. Synthesis of novel cubic Ni2Mo3N and its electronic structure regulation by vanadium doping towards high-efficient HER electrocatalyst .ELECTROCHIMICA ACTA.2020,337

131. 周鹏. High-efficient electrocatalytic overall water splitting over vanadium doped hexagonal Ni0.2Mo0.8N .应用催化-b.2020,263

132. 雷龙飞. Tuning the Conduction Band Potential of Bi-based Semiconductors Using a Combination of Organic Ligands .ChemSusChem.2020

133. 邢丹宁. Co-3(hexaiminotriphenylene)(2): A conductive two-dimensional pi-d conjugated metal-organic framework for highly efficient oxygen evolution reaction .应用催化-b.2020,278

134. liuyuanyuan , wangzeyan , Zhaoke Zheng , Dai Ying , Huang Baibiao  and CHENG Hefeng. Oxygen‐Vacancy‐Enhanced Singlet Oxygen Production for Selective Photocatalytic Oxidation .ChemSusChem.2020

135. 宋新华. Polar Molecular Modification onto BiOBr to Regulate Molecular Oxygen Activation .The Journal of Physical Chemestry C.2019,123 (25):15599

136. liuyuanyuan , wangzeyan , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying , Huang Baibiao  and wangjiajia. Enhanced photocatalytic activity towards H-2 evolution over NiO via phosphonic acid surface modification with different functional groups .International journal of hydrogen energy.2019,44 (31):16575

137. 安阳. Improving the photocatalytic hydrogen evolution of UiO-67 by incorporating Ce4+-coordinated bipyridinedicarboxylate ligands .Science Bulletin.2019,64 (20):1502

138. 张若倩. Selective photocatalytic conversion of alcohol to aldehydes by singlet oxygen over Bi-based metal-organic frameworks under UV-vis light irradiation .应用催化-b.2019,254 :463

139. 张若倩. Monomolecular VB2-doped MOFs for photocatalytic oxidation with enhanced stability, recyclability and selectivity .Journal of Materials Chemistry A.2019,7 (47):26934

140. liuyuanyuan , Huang Baibiao , wangzeyan , Zhaoke Zheng , Dai Ying  and zhoupeng. Enhanced electrocatalytic HER performance of non-noble metal nickel by introduction of divanadium trioxide .ELECTROCHIMICA ACTA.2019,320

141. zhanjie , Dai Ying , zhou guangjun , Yu Fapeng , WangPeng , Huang Baibiao  and yu zaizai. Synthesis of high efficient and stable plasmonic photocatalyst Ag/AgNbO3 with specific exposed crystal-facets and intimate heterogeneous interface via combustion route .Applied surface science.2019,488 :485

142. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 张若倩. Post-synthetic platinum complex modification of a triazine based metal organic frameworks for enhanced photocatalytic H-2 evolution .journal of solid state chemistry.2019,271 :260

143. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 邢丹宁. Enhanced photocatalytic hydrogen evolution of CdWO4 through polar organic molecule modification .INTERNATIONAL JOURNAL OF HYDROGEN ENERGY Journal.2019,44 (10):4754

144. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 张若倩. A water-stable triazine-based metal-organic framework as an efficient adsorbent of Pb(II) ions .COLLOIDS AND SURFACES A-PHYSICOCHEMICAL AND ENGINEERING ASPECTS Journal.2019,560 :315

145. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , Dai Ying , qinxiaoyan , zhangxiaoyang  and 安阳. Stabilizing the titanium-based metal organic frameworks in water by metal cations with empty or partially-filled d orbitals .Journal of Colloid and Interface Science 2012.2019,533 :9

146. wangzeyan , liyingjie , Huang Baibiao , Zhaoke Zheng , WangPeng , liuyuanyuan , zhangxiaoyang , qinxiaoyan  and Dai Ying. Graphitic carbon nitride tetragonal hollow prism with enhanced photocatalytic hydrogen evolution .International Journal of Hydrogen Energy .2019,44 (54):28780

147. wangzeyan , Huang Baibiao , WangPeng , liuyuanyuan , zhangxiaoyang , qinxiaoyan  and Dai Ying. Endotaxial Growth of [100]-oriented TaON Films on LiTaO3 Single Crystals for Enhanced Photoelectrochemical Water Splitting .Solar RRL.2018,2 :1700243

148. wangzeyan , Huang Baibiao , zhangxiaoyang , qinxiaoyan , WangPeng , liuyuanyuan , Dai Ying  and liyingjie. Fabrication of In2O3/ZnO hetero-epitaxial-junctions with enhanced PEC performances .Materials Today Energy.2017,6 :65

149. Huang Baibiao , WangPeng , qinxiaoyan , zhangxiaoyang  and Dai Ying. Synthesis of novel visible light response Ag10Si4O13 photocatalyst .Applied Catalysis B: Environmental.2016,199 :315

150. Dai Ying , zhangxiaoyang , qinxiaoyan , Huang Baibiao , jiangminhua , WangPeng , Zhaoke Zheng  and Myung-Hwan Whangbo. Highly Efficient Photocatalyst: TiO2 Microspheres Produced from TiO2 Nanosheets with a High Percentage of Reactive {001} Facets .Chem. Eur. J. .2009

151. zhangxiaoyang , Dai Ying , qinxiaoyan , Huang Baibiao , wangzeyan , WangPeng  and Zhaoke Zheng. Crystal Faces of Cu2O and Their Stabilities in Photocatalytic Reactions .J. Phys. Chem. C.2009

152. Huang Baibiao , WangPeng , qinxiaoyan , zhangxiaoyang  and Dai Ying. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B: Environmental.2016,203 :282

153. Huang Baibiao , WangPeng , qinxiaoyan , Dai Ying  and zhangxiaoyang. Synthesis of Mn-doped ZnS microspheres with enhanced visible light photocatalytic activity .Applied Surface Science.2016,391 :557

154. Dai Ying , WangPeng , Huang Baibiao , zhangqianqian , wangzeyan , liuyuanyuan , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang  and 梁希壮. Ag2ZnSnS4/ Mo- mesh photoelectrode prepared by electroplating for efficient photoelectrochemical hydrogen generation .Journal of Materials Chemistry A.2019,7 (4):1647

155. WangPeng , Dai Ying , Huang Baibiao  and 朱相林. Porous Ag-ZnO microspheres as efficient photocatalyst for methane and ethylene oxidation: Insight into the role of Ag particles .Applied Surface Science.2018,456 :493

156. Huang Baibiao , Zhaoke Zheng , WangPeng , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang  and 郑海龙. Ag-n(+) quantum dots obtained via in situ photodeposition method as photocatalytic CO2 reduction cocatalyst: Borrowing redox conversion between Ag+ and Ag-0 .Applied Catalysis B-Environmental.2019,243 :381

157. Xi Baojuan , WangPeng , xiong shenglin  and 开爽爽. An innovative Au-CdS/ZnS-RGO architecture for efficient photocatalytic hydrogen evolution .journal of materials chemistry A.2018,6 (7):2895

158. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Guizheng Zou , Dai Ying  and wuyaqiang. Composite of CH3NH3PbI3 with Reduced Graphene Oxide as a Highly Efficient and Stable Visible-Light Photocatalyst for Hydrogen Evolution in Aqueous HI Solution .Advanced Materials.2018,30 (7)

159. zhoupeng , Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 周鹏. Accelerated electrocatalytic hydrogen evolution on non-noble metal containing trinickel nitride by introduction of vanadium nitride .Journal of Materials Chemistry A.2019,7 (10):5513

160. zhangxiaoyang , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Dai Ying , Huang Baibiao , qinxiaoyan  and 刘小磊. Synthesis of a WO3 photocatalyst with high photocatalytic activity and stability using synergetic internal Fe3+ doping and superficial Pt loading for ethylene degradation under visible-light irradiation .Catalysis Science and Technology.2019,9 (3):652

161. WangPeng , zhangqianqian , Huang Baibiao , wangzeyan , liuyuanyuan , Zhaoke Zheng , Dai Ying  and 刘小磊. The synergistic effect of light irradiation and interface engineering of the Co(OH)(2)/MoS2 heterostructure to realize the efficient alkaline hydrogen evolution reaction .ELECTROCHIMICA ACTA.2019,299 :618

162. zhangxiaoyang , WangPeng , zhangqianqian , Huang Baibiao , wangzeyan , liuyuanyuan , Zhaoke Zheng , Dai Ying , qinxiaoyan  and 刘小磊. Synthesis of MoS2/Ni3S2 heterostructure for efficient electrocatalytic hydrogen evolution reaction through optimizing the sulfur sources selection .Applied Surface Science.2018,459 :422

163. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 刘福燕. Porous Co3O4 nanosheets as a high-performance non-enzymatic sensor for glucose detection .Analytical and Bioanalytical Chemistry.2018,410 (29):7663

164. wangzeyan , Huang Baibiao , Zhaoke Zheng , WangPeng , liuyuanyuan  and Dai Ying. Enhanced selectivity and activity for electrocatalytic reduction of CO2 to CO on an anodized Zn/carbon/Ag electrode .Journal of Materials Chemistry A.2019,7 :16685

165. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , Zhaoke Zheng , liuyuanyuan , Dai Ying  and 管子涵. Perovskite photocatalyst CsPbBr3-xIx with a bandgap funnel structure for H-2 evolution under visible light .Applied Catalysis B-Environmental.2019,245 :522

166. WangPeng , Huang Baibiao , zhangqianqian  and 翟慧珊. Enhanced photocatalytic H2 production of Mn0.5Cd0.5S solid solution through loading transition metal sulfides XS (X = Mo, Cu, Pd) cocatalysts .Applied Surface Science.2018,430 (430):515

167. Dai Ying , Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , Zhaoke Zheng , liyingjie  and 李慧亮. Effect of the intra- and inter-triazine N-vacancies on the photocatalytic hydrogen evolution of graphitic carbon nitride .Chemical Engineering Journal.2019,369 :263

168. Huang Baibiao , wangzeyan , WangPeng , Zhaoke Zheng , liuyuanyuan , Dai Ying , liyingjie  and 黄慧宁. Efficient near-infrared photocatalysts based on NaYF4:Yb3+,Tm3+@ NaYF4:Yb3+, Nd3+@TiO2 core@shell nanoparticles .Chemical Engineering Journal.2019,361 :1089

169. Huang Baibiao , WangPeng , wangzeyan , liuyuanyuan , Zhaoke Zheng , zhangqianqian , zhangxiaoyang , Dai Ying  and 朱相林. Co3O4 nanobelt arrays assembled with ultrathin nanosheets as highly efficient and stable electrocatalysts for the chlorine evolution reaction .Journal of Materials Chemistry A.2018,6 (26):12718

170. zhangqianqian , Huang Baibiao , WangPeng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 李鑫. Self-assembled supramolecular system PDINH on TiO2 surface enhances hydrogen production .Journal of Colloid and interface science.2018,525 :136

171. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , Dai Ying , zhangxiaoyang , liuyuanyuan  and 梁希壮. Adsorption of gaseous ethylene via induced polarization on plasmonicphotocatalyst Ag/AgCl/TiO2and subsequent photodegradation .应用催化-b.2018,220 :356

172. WangPeng , zhangqianqian , Dai Ying , Huang Baibiao  and 朱相林. Amorphous TiO2‐modified CuBi2O4 Photocathode with enhanced photoelectrochemical hydrogen production activity .中国催化学报.2018,39 :1704

173. zhangxiaoyang , WangPeng , zhangqianqian , Huang Baibiao , wangzeyan , liuyuanyuan , Dai Ying , qinxiaoyan  and 刘小磊. Synthesis of synergetic phosphorus and cyano groups (eC^N) modified g- C3N4 for enhanced photocatalytic H2 production and CO2 reduction under visible light irradiation .应用催化-B.2018,232 :521

174. WangPeng , Huang Baibiao , Dai Ying , qinxiaoyan , zhangxiaoyang , wangzeyan , liuyuanyuan  and 娄在祝. Enhancing Charge Separation in Photocatalysts with Internal Polar Electric Fields .chemphotochem.2017,1 :136

175. WangPeng , Huang Baibiao , zhangqianqian , qinxiaoyan , zhangxiaoyang  and 朱相林. Fabrication of large size nanoporous BiVO4 photoanode by a printing-like method for efficient solar water splitting application .Ctalysis today.2019

176. Dai Ying , WangPeng , Huang Baibiao , zhangqianqian , wangzeyan , liuyuanyuan , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang  and 梁希壮. Effects of Ag Incorporation on the Band Structures and Conductivity Types of (Cu1-xAgx)2ZnSnS4 Solid Solutions .Chemphotochem.2018,2 :811

177. Huang Baibiao , WangPeng , wangzeyan , Zhaoke Zheng , Dai Ying  and wuyaqiang. Enhancing the Photocatalytic Hydrogen Evolution Activity of Mixed- Halide Perovskite CH3NH3PbBr3?xIx Achieved by Bandgap Funneling of Charge Carriers .Acs catalysis.2018,8 :10349

178. WangPeng , Huang Baibiao , zhangqianqian , wangzeyan , Dai Ying  and 刘小磊. Efficient photocatalytic H2 production via rational design of synergistic spatially-separated dual cocatalysts modified Mn0.5Cd0.5S photocatalyst under visible light irradiation .Chemical Engineering Journal.2018,337 :480

179. Dai Ying , Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Zhaoke Zheng  and 梁希壮. Design and synthesis of porous M-ZnO/CeO2 microspheres as efficient plasmonic photocatalysts for nonpolar gaseous molecules oxidation: Insight into the role of oxygen vacancy defects and M=Ag, Au nanoparticles .应用催化B.2019,260 :118151

180. WangPeng , zhangqianqian , Dai Ying , Huang Baibiao  and 朱相林. 非晶TiO_2修饰CuBi_2O_4光阴极增强其光电化学产氢活性(英文) .催化学报.2018 (10)

181. WangPeng , Huang Baibiao , zhangqianqian  and 翟慧珊. Enhanced photocatalytic H<inf>2</inf>production of Mn<inf>0.5</inf>Cd<inf>0.5</inf>S solid solution through loading transition metal sulfides XS (X = Mo .APPL SURF SCI.2018,430 :515

182. WangPeng , zhangqianqian , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan  and 朱相林. Novel high-efficiency visible-light responsive Ag<inf>4</inf>(GeO<inf>4</inf>) photocatalyst .Catal. Sci. Technolog..2017,7 (11):2318

183. liuyuanyuan , wangzeyan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 姜在勇. Photocatalytic reduction of CO<inf>2</inf>to methanol by three-dimensional hollow structures of Bi<inf>2</inf>WO<inf>6</inf>quantum dots .Appl. Catal. B Environ..2017,219 :209

184. WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , Huang Baibiao  and 朱相林. CdS-MoS<inf>2</inf>heterostructures on Mo substrates via in situ sulfurization for efficient photoelectrochemical hydrogen generation .Rsc Adv..2017,7 (71):44626

185. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , zhangqianqian , Dai Ying  and 李鑫. Precisely locate Pd-Polypyrrole on TiO<inf>2</inf>for enhanced hydrogen production .Int J Hydrogen Energy.2017,42 (40):25195

186. wangzeyan , Huang Baibiao , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying , zhou guangjun  and 黄慧宁. Intense Single Red Emission Induced by Near-Infrared Irradiation Using a Narrow Bandgap Oxide BiVO4 as the Host for Yb3+ and Tm3+ Ions .Advanced Optical Materials.2018,6 (15)

187. Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 李慧亮. Fabrication of carbon bridged g-C3N4 through supramolecular self-assembly for enhanced photocatalytic hydrogen evolution .Applied Catalysis B-Environmental.2018,229 :114

188. wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , liuyuanyuan , WangPeng , liyingjie  and 张博. Doping strategy to promote the charge separation in BiVO<inf>4</inf>photoanodes .Appl. Catal. B Environ..2017,211 :258

189. liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan , WangPeng  and 徐本燕. Enhancing the photocatalytic activity of BiOX (X = Cl, Br, and I), (BiO)<inf>2</inf>CO<inf>3</inf>and Bi<inf>2</inf>O<inf>3</inf>by modifying their surf .J. Mater. Chem. A.2017,5 (27):14406

190. Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 王丛. TiN nanosheet arrays on Ti foils for high-performance supercapacitance .RSC advances.2018,8 (23):12841

191. wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , WangPeng , liuyuanyuan , Huang Baibiao  and 刘洪帅. Photocatalytic degradation of ethylene by Ga2O3 polymorphs .RSC advances.2018,8 (26):14328

192. Huang Baibiao , wangzeyan , Zhaoke Zheng , WangPeng , liuyuanyuan , zhangxiaoyang , qinxiaoyan , Dai Ying  and 张海鹏. Fabrication of BiVO4 photoanode consisted of mesoporous nanoparticles with improved bulk charge separation efficiency .Applied Catalysis B-Environmental.2018,238 :586

193. Huang Baibiao , WangPeng , zhangqianqian , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan  and 朱相林. Novel high-efficiency visible-light responsive Ag-4(GeO4) photocatalyst .CATALYSIS SCIENCE & TECHNOLOGY.2017, 7 (11):2318

194. Huang Baibiao , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan , WangPeng  and 徐本燕. Enhancing the photocatalytic activity of BiOX (X = Cl, Br, and I), (BiO)(2)CO3 and Bi2O3 by modifying their surfaces with polar organic anions, 4-substituted thiophenolates .journal of materials chemistry A.2017, 5 (27):14406

195. Huang Baibiao , wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , liuyuanyuan , WangPeng , liyingjie  and 张博. Doping strategy to promote the charge separation in BiVO4 photoanodes .Applied Catalysis B-Environmental.2017, 211 :258

196. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , Dai Ying  and 刘小磊. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B-Environmental.2017, 203 :282

197. WangPeng , Huang Baibiao , Dai Ying , zhangxiaoyang , qinxiaoyan  and 王璐. Synthesis of Mn-doped ZnS microspheres with enhanced visible light photocatalytic activity .Applied Surface Science.2017, 391 :557

198. liuyuanyuan , wangzeyan , WangPeng , Dai Ying , qinxiaoyan , zhangxiaoyang , Huang Baibiao  and 安阳. Photocatalytic Overall Water Splitting over MIL-125(Ti) upon CoPi and Pt Co-catalyst Deposition .chemistryopen.2017, 6 (6):701

199. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 姜在勇. Photocatalytic reduction of CO2 to methanol by three-dimensional hollow structures of Bi2WO6 quantum dots .Applied Catalysis B-Environmental.2017, 219 :209

200. WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , Huang Baibiao  and 朱相林. Cds-MoS2 heterostructures on Mo substrates via in situ sulfurization for efficient photoelectrochemical hydrogen generation .RSC advances.2017, 7 (71):44626

201. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Synthesis of novel visible light response Ag10Si4O13 photocatalyst .Applied Catalysis B: Environmental.2016,199 :315

202. Dai Ying , zhangxiaoyang , qinxiaoyan , Huang Baibiao , jiangminhua , WangPeng , Zhaoke Zheng  and Myung-Hwan Whangbo. Highly Efficient Photocatalyst: TiO2 Microspheres Produced from TiO2 Nanosheets with a High Percentage of Reactive {001} Facets .Chem. Eur. J. .2009

203. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , zhangqianqian , Dai Ying  and 李鑫. Precisely locate Pd-Polypyrrole on TiO2 for enhanced hydrogen production .International journal of hydrogen energy.2017, 42 (40):25195

204. Dai Ying , qinxiaoyan , Huang Baibiao , wangzeyan , WangPeng , Zhaoke Zheng  and zhangxiaoyang. Crystal Faces of Cu2O and Their Stabilities in Photocatalytic Reactions .J. Phys. Chem. C.2009

205. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B: Environmental.2016,203 :282

206. qinxiaoyan , Dai Ying , zhangxiaoyang , WangPeng  and Huang Baibiao. Synthesis of Mn-doped ZnS microspheres with enhanced visible light photocatalytic activity .Applied surface science.2016,391 :557

207. WangPeng , zhangqianqian , wangzeyan , Dai Ying , zhangxiaoyang , liuyuanyuan  and 梁希壮. Adsorption of gaseous ethylene via induced polarization on plasmonic photocatalyst Ag/AgCl/TiO<inf>2</inf>and subsequent photodegradation .Appl. Catal. B Environ..2018,220 :356

208. Dai Ying , WangPeng , Huang Baibiao , zhangqianqian , wangzeyan , liuyuanyuan , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang  and 梁希壮. Ag2ZnSnS4/ Mo- mesh photoelectrode prepared by electroplating for efficient photoelectrochemical hydrogen generation .Journal of Materials Chemistry A.2019,7 (4):1647

209. WangPeng , Dai Ying , Huang Baibiao  and 朱相林. Porous Ag-ZnO microspheres as efficient photocatalyst for methane and ethylene oxidation: Insight into the role of Ag particles .Applied surface science.2018,456 :493

210. Xi Baojuan , WangPeng , xiong shenglin  and 开爽爽. An innovative Au-CdS/ZnS-RGO architecture for efficient photocatalytic hydrogen evolution .journal of materials chemistry A.2018,6 (7):2895

211. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Guizheng Zou , Dai Ying  and wuyaqiang. Composite of CH3NH3PbI3 with Reduced Graphene Oxide as a Highly Efficient and Stable Visible-Light Photocatalyst for Hydrogen Evolution in Aqueous HI Solution .Advanced Materials.2018,30 (7)

212. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , Zhaoke Zheng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 周鹏. Accelerated electrocatalytic hydrogen evolution on non-noble metal containing trinickel nitride by introduction of vanadium nitride .Journal of Materials Chemistry A.2019,7 (10):5513

213. zhangxiaoyang , WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , Dai Ying , Huang Baibiao , qinxiaoyan  and 刘小磊. Synthesis of a WO3 photocatalyst with high photocatalytic activity and stability using synergetic internal Fe3+ doping and superficial Pt loading for ethylene degradation under visible-light irradiation .Catalysis Science and Technology.2019,9 (3):652

214. WangPeng , zhangqianqian , Huang Baibiao , wangzeyan , liuyuanyuan , Zhaoke Zheng , Dai Ying  and 刘小磊. The synergistic effect of light irradiation and interface engineering of the Co(OH)(2)/MoS2 heterostructure to realize the efficient alkaline hydrogen evolution reaction .ELECTROCHIMICA ACTA.2019,299 :618

215. zhangxiaoyang , WangPeng , zhangqianqian , Huang Baibiao , wangzeyan , liuyuanyuan , Zhaoke Zheng , Dai Ying , qinxiaoyan  and 刘小磊. Synthesis of MoS2/Ni3S2 heterostructure for efficient electrocatalytic hydrogen evolution reaction through optimizing the sulfur sources selection .Applied surface science.2018,459 :422

216. Huang Baibiao , WangPeng , zhangqianqian , wangzeyan , Zhaoke Zheng , liuyuanyuan , Dai Ying  and 管子涵. Perovskite photocatalyst CsPbBr3-xIx with a bandgap funnel structure for H-2 evolution under visible light .Applied Catalysis B-Environmental.2019,245 :522

217. Huang Baibiao , WangPeng , wangzeyan , liuyuanyuan , Zhaoke Zheng , zhangqianqian , zhangxiaoyang , Dai Ying  and 朱相林. Co3O4 nanobelt arrays assembled with ultrathin nanosheets as highly efficient and stable electrocatalysts for the chlorine evolution reaction .journal of materials chemistry A.2018,6 (26):12718

218. zhangqianqian , Huang Baibiao , WangPeng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 李鑫. Self-assembled supramolecular system PDINH on TiO2 surface enhances hydrogen production .Journal of Colloid and interface science.2018,525 :136

219. Huang Baibiao , Zhaoke Zheng , WangPeng , liuyuanyuan , Dai Ying  and wangzeyan. Enhanced selectivity and activity for electrocatalytic reduction of CO2 to CO on an anodized Zn/carbon/Ag electrode .Journal of Materials Chemistry A.2019,7 :16685

220. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Synthesis of novel visible light response Ag10Si4O13 photocatalyst .Applied Catalysis B: Environmental.2016,199 :315

221. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B: Environmental.2016,203 :282

222. qinxiaoyan , Dai Ying , zhangxiaoyang , WangPeng  and Huang Baibiao. Synthesis of Mn-doped ZnS microspheres with enhanced visible light photocatalytic activity .Applied surface science.2016,391 :557

223. Huang Baibiao , Zhaoke Zheng , WangPeng , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang  and 郑海龙. Ag-n(+) quantum dots obtained via in situ photodeposition method as photocatalytic CO2 reduction cocatalyst: Borrowing redox conversion between Ag+ and Ag-0 .Applied Catalysis B-Environmental.2019,243 :381

224. Dai Ying , Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , Zhaoke Zheng , liyingjie  and 李慧亮. Effect of the intra- and inter-triazine N-vacancies on the photocatalytic hydrogen evolution of graphitic carbon nitride .Chemical Engineering Journal.2019,369 :263

225. wangzeyan , WangPeng , Zhaoke Zheng , liuyuanyuan , Dai Ying , liyingjie , Huang Baibiao  and 黄慧宁. Efficient near-infrared photocatalysts based on NaYF4:Yb3+,Tm3+@ NaYF4:Yb3+, Nd3+@TiO2 core@shell nanoparticles .Chemical Engineering Journal.2019,361 :1089

226. Dai Ying , zhangxiaoyang , qinxiaoyan , WangPeng  and Huang Baibiao. Synthesis of Mn-doped ZnS microspheres with enhanced visible light photocatalytic activity .Applied surface science.2016,391 :557

227. wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , liuyuanyuan , WangPeng , liyingjie  and 张博. Doping strategy to promote the charge separation in BiVO<inf>4</inf>photoanodes .Appl. Catal. B Environ..2017,211 :258

228. Huang Baibiao , wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , liuyuanyuan , WangPeng , liyingjie  and 张博. Doping strategy to promote the charge separation in BiVO4 photoanodes .Applied Catalysis B-Environmental.2017, 211 :258

229. Huang Baibiao , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan , WangPeng  and 徐本燕. Enhancing the photocatalytic activity of BiOX (X = Cl, Br, and I), (BiO)(2)CO3 and Bi2O3 by modifying their surfaces with polar organic anions, 4-substituted thiophenolates .journal of materials chemistry A.2017, 5 (27):14406

230. liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan , WangPeng  and 徐本燕. Enhancing the photocatalytic activity of BiOX (X = Cl, Br, and I), (BiO)<inf>2</inf>CO<inf>3</inf>and Bi<inf>2</inf>O<inf>3</inf>by modifying their surf .J. Mater. Chem. A.2017,5 (27):14406

231. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Synthesis of novel visible light response Ag10Si4O13 photocatalyst .Applied Catalysis B: Environmental.2016,199 :315

232. qinxiaoyan , zhangxiaoyang , Dai Ying , WangPeng  and Huang Baibiao. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B: Environmental.2016,203 :282

233. wangzeyan , zhangxiaoyang , qinxiaoyan , Dai Ying , WangPeng , liuyuanyuan , Huang Baibiao  and 刘洪帅. Photocatalytic degradation of ethylene by Ga2O3 polymorphs .RSC advances.2018,8 (26):14328

234. liuyuanyuan , wangzeyan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 姜在勇. Photocatalytic reduction of CO<inf>2</inf>to methanol by three-dimensional hollow structures of Bi<inf>2</inf>WO<inf>6</inf>quantum dots .Appl. Catal. B Environ..2017,219 :209

235. Huang Baibiao , liuyuanyuan , wangzeyan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 姜在勇. Photocatalytic reduction of CO2 to methanol by three-dimensional hollow structures of Bi2WO6 quantum dots .Applied Catalysis B-Environmental.2017, 219 :209

236. Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying  and 李慧亮. Fabrication of carbon bridged g-C3N4 through supramolecular self-assembly for enhanced photocatalytic hydrogen evolution .Applied Catalysis B-Environmental.2018,229 :114

237. Huang Baibiao , wangzeyan , Zhaoke Zheng , WangPeng , liuyuanyuan , zhangxiaoyang , qinxiaoyan , Dai Ying  and 张海鹏. Fabrication of BiVO4 photoanode consisted of mesoporous nanoparticles with improved bulk charge separation efficiency .Applied Catalysis B-Environmental.2018,238 :586

238. liuyuanyuan , wangzeyan , WangPeng , Dai Ying , qinxiaoyan , zhangxiaoyang , Huang Baibiao  and 安阳. Photocatalytic Overall Water Splitting over MIL-125(Ti) upon CoPi and Pt Co-catalyst Deposition .chemistryopen.2017, 6 (6):701

239. Huang Baibiao , wangzeyan , liuyuanyuan , WangPeng , qinxiaoyan , zhangxiaoyang , Dai Ying  and 王丛. TiN nanosheet arrays on Ti foils for high-performance supercapacitance .RSC advances.2018,8 (23):12841

240. wangzeyan , Huang Baibiao , WangPeng , zhangxiaoyang , qinxiaoyan , Dai Ying , zhou guangjun  and 黄慧宁. Intense Single Red Emission Induced by Near-Infrared Irradiation Using a Narrow Bandgap Oxide BiVO4 as the Host for Yb3+ and Tm3+ Ions .Advanced Optical Materials.2018,6 (15)

241. WangPeng , Huang Baibiao , zhangqianqian  and 翟慧珊. Enhanced photocatalytic H<inf>2</inf>production of Mn<inf>0.5</inf>Cd<inf>0.5</inf>S solid solution through loading transition metal sulfides XS (X = Mo .APPL SURF SCI.2018,430 :515

242. WangPeng , zhangqianqian , Dai Ying , Huang Baibiao  and 朱相林. 非晶TiO_2修饰CuBi_2O_4光阴极增强其光电化学产氢活性(英文) .催化学报.2018 (10)

243. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , Dai Ying  and 刘小磊. Highly efficient and noble metal-free NiS modified MnxCd1-xS solid solutions with enhanced photocatalytic activity for hydrogen evolution under visible light irradiation .Applied Catalysis B-Environmental.2017, 203 :282

244. Zhaoke Zheng , qinxiaoyan , Dai Ying , WangPeng , wangzeyan , Huang Baibiao  and zhangxiaoyang. Crystal Faces of Cu2O and Their Stabilities in Photocatalytic Reactions .2009

245. WangPeng , Dai Ying , zhangxiaoyang , qinxiaoyan , Huang Baibiao , Zhaoke Zheng , jiangminhua  and Myung-Hwan Whangbo. Highly Efficient Photocatalyst: TiO2 Microspheres Produced from TiO2 Nanosheets with a High Percentage of Reactive {001} Facets .2009

246. WangPeng , zhangqianqian , wangzeyan , Dai Ying , zhangxiaoyang , liuyuanyuan  and 梁希壮. Adsorption of gaseous ethylene via induced polarization on plasmonic photocatalyst Ag/AgCl/TiO<inf>2</inf>and subsequent photodegradation .Appl. Catal. B Environ..2018,220 :356

247. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , zhangqianqian , Dai Ying  and 李鑫. Precisely locate Pd-Polypyrrole on TiO<inf>2</inf>for enhanced hydrogen production .Int J Hydrogen Energy.2017,42 (40):25195

248. Huang Baibiao , WangPeng , zhangqianqian , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan  and 朱相林. Novel high-efficiency visible-light responsive Ag-4(GeO4) photocatalyst .CATALYSIS SCIENCE & TECHNOLOGY.2017, 7 (11):2318

249. WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , Huang Baibiao  and 朱相林. CdS-MoS<inf>2</inf>heterostructures on Mo substrates via in situ sulfurization for efficient photoelectrochemical hydrogen generation .Rsc Adv..2017,7 (71):44626

250. WangPeng , zhangqianqian , qinxiaoyan , zhangxiaoyang , Dai Ying , wangzeyan  and 朱相林. Novel high-efficiency visible-light responsive Ag<inf>4</inf>(GeO<inf>4</inf>) photocatalyst .Catal. Sci. Technolog..2017,7 (11):2318

251. WangPeng , Huang Baibiao , qinxiaoyan , zhangxiaoyang , zhangqianqian , Dai Ying  and 李鑫. Precisely locate Pd-Polypyrrole on TiO2 for enhanced hydrogen production .International journal of hydrogen energy.2017, 42 (40):25195

252. WangPeng , zhangqianqian , wangzeyan , liuyuanyuan , qinxiaoyan , zhangxiaoyang , Dai Ying , Huang Baibiao  and 朱相林. Cds-MoS2 heterostructures on Mo substrates via in situ sulfurization for efficient photoelectrochemical hydrogen generation .RSC advances.2017, 7 (71):44626

Patens

1. 一种双等离子体耦合增强的WO###-Au及其制备方法与应用

2. 一种复合混卤钙钛矿光催化材料及其制备方法和应用

3. 光催化-电催化耦合碘循环实现纯水分解的系统与方法

4. 一种铜基催化电极及制备方法与其在电催化还原二氧化碳制乙烯的应用

5. 一种光催化重整塑料产过氧化氢光催化材料及其制备方法

6. 一种过渡金属单原子-氧化钨材料及其制备方法和应用

7. 一种FeOOH/In-BiVO4(L)光电阳极材料及其制备方法和应用

8. 高选择性光还原二氧化碳制甲烷的光催化材料及其制备方法和应用

9. 一种体块溴氧化铋单晶及其生长方法与应用

10. 集成化光阳极器件、电池及其制备方法与应用

11. 一种锂离子插层氧化钼材料及其制备方法和应用

12. 具有空间氧空位分布的BiVO4光催化材料及其制备方法与应用

13. 全无机卤化物钙钛矿复合材料及其制备方法与应用

14. CABB/UCNT异质结复合光催化剂及其制备方法与应用

15. 一种采用钒酸铋光电极制氢的方法

16. 一种原位自选择性铜纳米枝晶材料及其制备方法和应用

17. 一种SrTiO3/TiO2异质外延光催化剂及其制备方法与应用

18. 一种Ov-Bi2O3催化剂及其制备方法与应用

19. 一种光化学与电化学解耦的光电阴极器件及其制备方法与应用

20. 具有光热转换性能的铁基MOFs材料及其制备方法与应用

21. 铜团簇修饰含氧空位的二氧化钛纳米片光催化剂及其制备方法与应用

22. 一种等离子体光催化材料及在二氧化碳环加成反应的应用

23. 卤化物钙钛矿基铂单原子光催化材料及其制备方法与应用

24. 具有光催化CO2还原性能的四方相BiVO4材料及其制备方法和应用

25. 双贵金属负载纳米二氧化钛及其制备方法和应用

26. 一种二氧化碳还原制乙烯催化剂、催化电极及制备方法

27. 铋基金属有机框架材料在作为光控药物载体中的应用

28. 一种原位光辅助铜沉积光催化剂的制备方法及原子层沉积装置

29. 一种双助催化剂负载的光催化剂及其制备方法与应用

30. 一种光催化剂、其制备方法、应用及光催化塑料重整方法

31. 一种硼修饰的氮化碳材料及其制备方法和应用

32. 一种二氧化碳还原光催化剂及其制备方法与应用

33. 具有光热协同效应的三氧化钨薄膜催化剂及其制备方法与应用

34. 一种Z型光催化剂及其制备方法与应用

35. 半导体光催化材料及制备方法与在制备亚胺中的应用

36. 一种铋基金属有机框架及其制备方法与应用

37. Pt-Au纳米棒及制备方法与在降解对硝基苯酚中的应用

38. 含硼锆基金属有机框架材料UiO-67-B及其制备方法与应用

39. 钾插层氧化钼纳米阵列材料及其制备方法和应用

40. 一种非晶态镍铁基硼化物纳米材料及其制备方法与应用

41. 一种钒酸铋的制备方法

42. 等离子体光催化材料及制备方法与在制备苯胺中的应用

43. 一种钒酸铋陶瓷光阳极及其制备方法与应用

44. 单颗粒等离子体光催化剂、单颗粒荧光检测方法及装置

45. 一种交替沉积的光催化剂及其制备方法与应用

46. 连续调控氧化锌陶瓷光吸收性质的方法、氧化锌陶瓷及制备方法

47. 一种具有氧空位的二氧化锰超长纳米线催化剂及其制备方法与应用

48. CO2环加成反应用铋基MOFs光催化剂及其制备方法和应用

49. 一种钒酸铋光阳极及其制备方法与应用

50. 一种具有多级结构的NiFe-PBAs-F催化剂及其制备方法与应用

51. 一种银基金属有机框架材料及其制备方法和应用

52. 一种N-NiMoO4/Ni3N电极材料及其制备方法和应用

53. 一种氧化钴纳米薄片析氯电极及其制备方法与应用

54. 一种铋基金属有机框架材料及其制备方法和应用

55. 一种等离子体合金光催化材料及制备方法和应用

56. 一种钒酸铋陶瓷光阳极的制备及其光电化学稳定性应用

57. 一种含硼的锆基金属有机框架材料及其制备方法与应用

58. 一种铋/锑基钙钛矿、光催化材料及其制备方法和应用

59. 一种二氧化碳还原制乙烯的催化剂、电极及方法

60. 一种Fe2O3薄膜电极的制备方法及其在光电化学葡萄糖传感器的应用

61. 一种具有可见光响应的Ag4(GeO4)光催化剂及其制备方法和应用

62. 一种TiO2-Pd-PPy复合光催化剂及其制备方法

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