Novel Preparation Strategy of Graphdiyn (Cnh2n-2): One-Pot Conjugation and S-Scheme Heterojunctions Formed with Mop Characterized with in Suit Xps for Efficiently Photocatalytic Hydrogen Evolution

[1]  Peng Zhang,et al.  Solar to H2O2 in-situ generation and utilization: A self-cyclable photocatalytic Fenton-like system , 2023, Chinese Journal of Catalysis.

[2]  Zhiliang Jin,et al.  Graphdiyne (CnH2n-2)-Based GDY/CuI/MIL-53(Al) S-Scheme Heterojunction for Efficient Hydrogen Evolution. , 2022, Langmuir : the ACS journal of surfaces and colloids.

[3]  Xiaohua Ma,et al.  Phosphorus-modified two-dimensional graphdiyne (CnH2n-2)/ZnCdS forms S-scheme heterojunctions for photocatalytic hydrogen production. , 2022, Nanoscale.

[4]  Zhiliang Jin,et al.  Surface-Induced Engineering: P-Induced Formation of Surface Bonding States Based on the ZIF Synthesis Strategy for Photocatalytic Hydrogen Evolution. , 2022, Inorganic chemistry.

[5]  A. Sivanantham,et al.  Using a CeO2 Quantum Dot Hole Extraction-layer for Enhanced Solar Water Splitting Activity of BiVO4 Photoanodes , 2022, Chemical Engineering Journal.

[6]  N. Tsubaki,et al.  Amorphous/Crystalline Heterojunction Interface Driving the Spatial Separation of Charge Carriers for Efficient Photocatalytic Hydrogen Evolution , 2022, Materials Today Physics.

[7]  Zhiliang Jin,et al.  Graphdiyne (G-Cnh2n-2) Based Co3s4 Anchoring and Edge-Covalently Modification Coupled with Carbon-Defects G-C3n4 for Photocatalytic Hydrogen Production , 2022, SSRN Electronic Journal.

[8]  Guilin Hu,et al.  Controllable Synthesis of Two-Dimensional Graphdiyne Films Catalyzed by a Copper(II) Trichloro Complex , 2022, ACS Catalysis.

[9]  Zhiliang Jin,et al.  Synergistic Effect of Bimetallic Sulfide Enhances the Performance of CdS Photocatalytic Hydrogen Evolution , 2022, Advanced Sustainable Systems.

[10]  M. Jaroniec,et al.  Non-Noble Plasmonic Metal-Based Photocatalysts. , 2022, Chemical reviews.

[11]  Jiaguo Yu,et al.  S-scheme ZnO/WO3 heterojunction photocatalyst for efficient H2O2 production , 2022, Journal of Materials Science & Technology.

[12]  Xin Guo,et al.  Construct 3D NiCo-LDH/Cu2O p-n heterojunction via electrostatic self-assembly for enhanced photocatalytic hydrogen evolution , 2022, Journal of Industrial and Engineering Chemistry.

[13]  X. Li,et al.  Design principle of S-scheme heterojunction photocatalyst , 2022, Journal of Materials Science & Technology.

[14]  Zhiliang Jin,et al.  EDA-assisted synthesis of multifunctional snowflake-Cu2S/CdZnS S-scheme heterojunction for improved the photocatalytic hydrogen evolution , 2022, Journal of Materials Science & Technology.

[15]  P. Zhang,et al.  Complex permittivity‐dependent plasma confinement‐assisted growth of asymmetric vertical graphene nanofiber membrane for high‐performance Li‐S full cells , 2022, InfoMat.

[16]  Xin Guo,et al.  Graphdiyne based GDY/CuI/NiO parallel double S-scheme heterojunction for efficient photocatalytic hydrogen evolution , 2022, 2D Materials.

[17]  P. Zhang,et al.  A “Three‐Region” Configuration for Enhanced Electrochemical Kinetics and High‐Areal Capacity Lithium–Sulfur Batteries , 2022, Advanced Functional Materials.

[18]  N. Tsubaki,et al.  Activating and Optimizing the Mos2@Moo3 S-Scheme Heterojunction Catalyst Through Interface Engineering to Form a Sulfur-Rich Surface for Photocatalyst Hydrogen Evolution , 2022, SSRN Electronic Journal.

[19]  Hongying Li,et al.  2D CeO2 and a Partially Phosphated 2D Ni-Based Metal-Organic Framework Formed an S-Scheme Heterojunction for Efficient Photocatalytic Hydrogen Evolution. , 2022, Langmuir : the ACS journal of surfaces and colloids.

[20]  Peng Zhang,et al.  Tracking charge transfer pathways in SrTiO3/CoP/Mo2C nanofibers for enhanced photocatalytic solar fuel production , 2022, Chinese Journal of Catalysis.

[21]  M. Fuji,et al.  Facile Preparation of Nanosized MoP as Cocatalyst Coupled with TiO2 for Highly Efficient Photocatalytic H2 Production , 2022, Catalysis Letters.

[22]  Xin Guo,et al.  Lotus-leaf-like Bi2O2CO3 nanosheet combined with Mo2S3 for higher photocatalytic hydrogen evolution , 2022, Separation and Purification Technology.

[23]  Xiao Lin,et al.  Graphene Aerogel-Based NiAl-LDH/g-C3N4 With Ultratight Sheet-Sheet Heterojunction for Excellent Visible-Light Photocatalytic Activity of CO2 Reduction , 2022, Applied Catalysis B: Environmental.

[24]  Zhiliang Jin,et al.  Design and synthesis of phosphating bimetallic CeCo-MOF for substaitially improved photocatalytic hydrogen evolution , 2022, Journal of Materials Chemistry C.

[25]  Jizhou Jiang,et al.  Advances in Nanostructured Silicon Carbide Photocatalysts , 2022, Acta Physico Chimica Sinica.

[26]  Hongying Li,et al.  In2O3-Modified Three-Dimensional Nanoflower MoSx Form S-scheme Heterojunction for Efficient Hydrogen Production , 2022, Acta Physico Chimica Sinica.

[27]  Hongying Li,et al.  Novel CuBr-assisted graphdiyne synthesis strategy and application for efficient photocatalytic hydrogen evolution , 2022, Journal of Materials Chemistry C.

[28]  Pengfei Zhu,et al.  ZIF-67 Dodecahedron Coupled with CoAl-Layered Double Hydroxide as S-Scheme Heterojunction for Efficient Visible-Light-Driven Hydrogen Evolution , 2022, SSRN Electronic Journal.

[29]  Jiaguo Yu,et al.  Emerging S‐Scheme Photocatalyst , 2021, Advanced materials.

[30]  N. Tsubaki,et al.  MoP@MoO3 S-scheme heterojunction in situ construction with phosphating MoO3 for high-efficient photocatalytic hydrogen production. , 2021, Nanoscale.

[31]  Xudong Jiang,et al.  Hollow tubular Co9S8 grown on In2O3 to form S-scheme heterojunction for efficient and stable hydrogen evolution , 2021, International Journal of Hydrogen Energy.

[32]  Peng Su,et al.  Effect of phosphating on NiAl-LDH layered double hydroxide form S-scheme heterojunction for photocatalytic hydrogen evolution , 2021, Molecular Catalysis.

[33]  Jiaguo Yu,et al.  TiO2/In2S3 S-scheme photocatalyst with enhanced H2O2-production activity , 2021, Nano Research.

[34]  Zhiliang Jin,et al.  A New Allotrope of Carbon—Graphdiyne (g‐CnH2n−2) Boosting with Mn0.2Cd0.8S form S‐Scheme Heterojunction for Efficient Photocatalytic Hydrogen Evolution , 2021, Advanced Materials Interfaces.

[35]  Peng Zhang,et al.  A flexible metallic TiC nanofiber/vertical graphene 1D / 2D heterostructured as active electrocatalyst for advanced Li–S batteries , 2021, InfoMat.

[36]  Zhiliang Jin,et al.  Graphdiyne Based Ternary GD-CuI-NiTiO3 S-Scheme Heterjunction Photocatalyst for Hydrogen Evolution. , 2021, ACS applied materials & interfaces.

[37]  A. Al-Ghamdi,et al.  A new heterojunction in photocatalysis: S-scheme heterojunction , 2021, Chinese Journal of Catalysis.

[38]  Shaoqing Song,et al.  S‐Scheme Photocatalytic Systems , 2021 .

[39]  Jinhua Ye,et al.  Solid-state synthesis of ultra-small freestanding amorphous MoP quantum dots for highly efficient photocatalytic H2 production , 2021 .

[40]  Hua Tang,et al.  Construction of LSPR-enhanced 0D/2D CdS/MoO3− S-scheme heterojunctions for visible-light-driven photocatalytic H2 evolution , 2021, Chinese Journal of Catalysis.

[41]  Zhiliang Jin,et al.  Rationally Designed Mn0.2Cd0.8S@CoAl LDH S-scheme Heterojunction for Efficient Photocatalytic Hydrogen Production , 2021, Acta Physico Chimica Sinica.

[42]  Yanbin Wang,et al.  Graphdiyne formed a novel CuI-GD/g-C3N4 S-scheme heterojunction composite for efficient photocatalytic hydrogen evolution , 2020 .

[43]  Jiaguo Yu,et al.  Unique S-scheme heterojunctions in self-assembled TiO2/CsPbBr3 hybrids for CO2 photoreduction , 2020, Nature Communications.

[44]  Zhiliang Jin,et al.  Performance of Ni-Cu bimetallic co-catalyst g-C3N4 nanosheets for improving hydrogen evolution , 2020 .

[45]  Jiaguo Yu,et al.  S-Scheme Heterojunction Photocatalyst , 2020, Chem.

[46]  Qingxiang Ma,et al.  Construction strategy of Mo-S@Mo-P heterojunction formed with in-situ phosphating Mo-S nanospheres toward efficient photocatalytic hydrogen production , 2020 .

[47]  Shaobin Wang,et al.  Photogenerated Electron Transfer Process in Heterojunctions: In Situ Irradiation XPS , 2020, Small Methods.

[48]  孙世刚,et al.  Construction of 1 D /1 D WO 3 Nanorod/TiO 2 Nanobelt Hybrid Heterostructure for Photocatalytic Application , 2020 .

[49]  Hongying Li,et al.  Based on amorphous carbon C@ZnxCd1-xS/Co3O4 composite for efficient photocatalytic hydrogen evolution , 2020 .

[50]  P. Fang,et al.  Consciously Constructing the Robust NiS/g-C3N4 Hybrids for Enhanced Photocatalytic Hydrogen Evolution , 2020, Catalysis Letters.

[51]  Zhiliang Jin,et al.  Unique synergistic effects of ZIF-9(Co)-derived cobalt phosphide and CeVO4 heterojunction for efficient hydrogen evolution , 2020, Chinese Journal of Catalysis.

[52]  S. Yin,et al.  Porous double-shell CdS@C3N4 octahedron derived by in situ supramolecular self-assembly for enhanced photocatalytic activity , 2019, Applied Catalysis B: Environmental.

[53]  C. Felser,et al.  Surface states in bulk single crystal of topological semimetal Co3Sn2S2 toward water oxidation , 2019, Science Advances.

[54]  S. Yin,et al.  Copper-mediated metal-organic framework as efficient photocatalyst for the partial oxidation of aromatic alcohols under visible-light irradiation: Synergism of plasmonic effect and schottky junction , 2019, Applied Catalysis B: Environmental.

[55]  Shengyuan A. Yang,et al.  Two-Dimensional Second-Order Topological Insulator in Graphdiyne. , 2019, Physical review letters.

[56]  Zhiliang Jin,et al.  Controllable design of Zn-Ni-P on g-C3N4 for efficient photocatalytic hydrogen production , 2019, Chinese Journal of Catalysis.

[57]  Z. Han,et al.  In situ fabrication of a direct Z-scheme photocatalyst by immobilizing CdS quantum dots in the channels of graphene-hybridized and supported mesoporous titanium nanocrystals for high photocatalytic performance under visible light , 2018, RSC advances.

[58]  Chaofan Yang,et al.  Synthesis of γ-graphyne by mechanochemistry and its electronic structure , 2018, Carbon.

[59]  J. Pan,et al.  CuI as Hole-Transport Channel for Enhancing Photoelectrocatalytic Activity by Constructing CuI/BiOI Heterojunction. , 2017, ACS applied materials & interfaces.

[60]  Daoben Zhu,et al.  Architecture of graphdiyne nanoscale films. , 2010, Chemical communications.