{"id":652,"date":"2011-04-05T21:10:20","date_gmt":"2011-04-05T13:10:20","guid":{"rendered":"http:\/\/brg.groups.xtbg.ac.cn\/?page_id=652"},"modified":"2026-02-15T19:07:04","modified_gmt":"2026-02-15T11:07:04","slug":"%e5%8f%91%e8%a1%a8%e8%ae%ba%e6%96%87","status":"publish","type":"page","link":"https:\/\/woodrefinery.com\/zhenfang\/%e5%8f%91%e8%a1%a8%e8%ae%ba%e6%96%87\/","title":{"rendered":"Publications"},"content":{"rendered":"\n
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ZHEN FANG\u2019S SELECTED PUBLICATIONS:<\/strong><\/p>\n

PUBLICATIONS: <\/strong>(*Corresponding author<\/strong>).<\/p>\n

(http:\/\/orcid.org\/0000-0002-7391-372X<\/a><\/span>)<\/p>\n

SELECTED\u00a0PAPERS (INT’L JOURNALS \u56fd\u9645\u671f\u520a\u8bba\u6587)<\/strong>:<\/span><\/p>\n

 <\/p>\n

    \n
  1. \u00a0 1.XR Meng, S Gao, JA. Kozinski, R Ruan, Zhen Fang*<\/strong>, Review – Biochar-based Oxygen Electrocatalysts for Advanced Zn-Air Batteries: Mechanisms, Applications, and Prospects, Chemical Engineering Journal<\/u><\/span> (IF 13.2), 529 (2026)<\/strong>, 172878. https:\/\/doi.org\/10.1016\/j.cej.2026.172878<\/a><\/li>\n
  2. \u00a0 2.Q Dong, S Tang*, Zhen Fang*<\/strong>, Efficient Lignin Removal from Rice Straw via<\/em> Alkaline-Freeze Combined with Hydrothermal Pretreatment to Obtain High-Titer Sugar for Microbial Lipid Production. Biomass and Bioenergy<\/u><\/span> (IF 5.8), 2026, 209<\/strong>, 108933. https:\/\/doi.org\/10.1016\/j.biombioe.2026.108933<\/a><\/li>\n
  3. \u00a0 3.C Gong, Z Ju, Q Lin*, X Lv, RL Smith Jr, L Xu, Y Cao, L Shuai*, Zhen Fang*<\/strong>, One-step Valorization of Cellulose Acetate Plastic Waste into 5-Hydroxymethylfurfural, Applied Catalysis B: Environment and Energy<\/u><\/span>, (IF 21.1), 381 (2026),<\/strong> 125880. https:\/\/doi.org\/10.1016\/j.apcatb.2025.125880<\/a><\/li>\n
  4. \u00a0 4.X Tao, XL Shi, ZJ Pan, XJ Zhao, ZY Zhu, LJ Xu, S Gao, W Chen, Zhen Fang<\/strong>, Biomass pyrolysis for phenolic compound production: Feedstock, Process, and Comprehensive Mechanism, Separation and Purification Technology<\/u>,<\/span> (IF 9), 384 (2026)<\/strong>, 136273. https:\/\/doi.org\/10.1016\/j.seppur.2025.136273<\/a>.<\/li>\n
  5. \u00a0 5.XR Meng, PD Wu, S Gao, Zhen Fang*, <\/strong>Regulation of Biochar Interfaces by Loading An Fe, N-Carbon Layer for the Oxygen Reduction Reaction in Acid Electrolytes, Applied Surface Science<\/u>,<\/span> (IF 6.9), 720, Part C (2026)<\/strong>, 165304. https:\/\/doi.org\/10.1016\/j.apsusc.2025.165304<\/a>.<\/li>\n
  6. \u00a0 6.TY Bi, TT Yang, ZY Ju, CY Dong, N Li, LJ Xu, W Chen, Zhen Fang<\/strong>, CX Gong, Insights into the Role Of Chemical-Assisted Densification in Structural Deconstruction and Enzymatic Hydrolysis Enhancement of Corn Stover, Renewable Energy<\/u><\/span>, (IF 9.1), 258 (2026)<\/strong>, 124924. https:\/\/doi.org\/10.1016\/j.renene.2025.124924<\/a>.<\/li>\n
  7. \u00a0 7.W Chen, XL Shi, Y Peng, YJ Wang, JY Li, YF Wang, CX Gong, CY Dong, S Gao, LJ Xu, Zhen Fang<\/strong>, HP Yang, Biomass Pyrolysis for N-Doped Biochar: Relationship among Preparation Process, N-Doped Biochar Properties, and Supercapacitors, Fuel<\/u>,<\/span> (IF 7.5), 404, Part C (2026)<\/strong>, 136372. https:\/\/doi.org\/10.1016\/j.fuel.2025.136372<\/a>.<\/li>\n
  8. \u00a0 8.HL Ma, YC Zhang, FX Xu, NF Ma, MF Li, GH Wang, MJ Huang, Zhen Fang*<\/strong>, LQ Jiang*, Fast Pyrolysis and Enzymatic Hydrolysis of Bagasse Cellulose from Synergistic Alkaline and Oxidative Pretreatment, Renewable Energy<\/u>,<\/span> (IF 9.1), 256, Part G (2026)<\/strong>, 124426. https:\/\/doi.org\/10.1016\/j.renene.2025.124426<\/a>.<\/li>\n
  9. \u00a0 9.ZJ Pan, XL Shi, ZY Zhu, X Tao, XJ Zhao, LJ Xu, S Gao, L Wang, W Chen, Zhen Fang<\/strong>, Joule Heating for Carbon Material Synthesis: Mechanisms, Material Evolution, and Sustainable Prospects, Renewable and Sustainable Energy Reviews<\/u>,<\/span> (IF 16.3), 226, Part B (2026)<\/strong>, 116290. https:\/\/doi.org\/10.1016\/j.rser.2025.116290<\/a>.<\/li>\n
  10. \u00a0 10.ZQ Wang, S Nanda, GX Xu, JA Kozinski, Zhen Fang*<\/strong>, Hydrogen Production from Biomass via<\/em> Hydrothermal Gasification Using Ni\u2013Ce Catalysts Supported on Kaolin, International Journal of Hydrogen Energy<\/u><\/span> (IF 8.3), 193, (2025)<\/strong>, 152353. https:\/\/doi.org\/10.1016\/j.ijhydene.2025.152353<\/a>.<\/li>\n
  11. \u00a0 11.GL Xie, Y Cao, SR Li, QQ Lu, W Chen, S Gao, W Qiu, C He, Zhen Fang<\/strong>, LJ Xu, BDE-Driven Sustainable Synthesis of Lignin-Derived Hydroxybenzonitriles via<\/em> Tandem Green Cyanation and Gas-Phase Hydrodeoxygenation. ACS Sustainable Chemistry & Engineering<\/u><\/span> (IF 7.3), 2025, 13 (32)<\/strong>, 13030-13041. https:\/\/pubs.acs.org\/doi\/10.1021\/acssuschemeng.5c04554<\/a><\/li>\n
  12. \u00a0 12.X Shi, Z Duan, W Chen, X Tao, YR Wang, CX Gong, S Gao, LJ Xu, Zhen Fang, <\/strong>HP Yang, Fast Pyrolysis-Derived Fe-N Co-Doped Biochar for Phenol Adsorption: Insights into Mechanisms from Experimental and Modeling Study, Energy<\/u><\/span> (IF 9.4), 341 (2025)<\/strong>, 139429. https:\/\/doi.org\/10.1016\/j.energy.2025.139429<\/a>.<\/li>\n
  13. \u00a0 13.HL Ma, FX Xu, YC Zhang, MJ Huang, MF Li, GH Wang, MX Huang, Zhen Fang*<\/strong> , LQ Jiang*, Non-unified Effects of Cellulose Allomorphs on Fast Pyrolysis and Enzymatic Hydrolysis, Industrial Crops and Products<\/u><\/span> (IF 6.2), 230 (2025)<\/strong>, 121153. https:\/\/doi.org\/10.1016\/j.indcrop.2025.121153<\/a><\/li>\n
  14. \u00a0 14.HL Ma, MF Li, YC Zhang, QH Huang, LQ Jiang, Zhen Fang<\/strong>, Nearly 100% Selective Hydrolysis of Pyrolytic Sugar over Sustainable Carbon Catalysts Enables Highly Efficient Production of Bioethanol, Bioresource Technology<\/u><\/span> (IF 9), 435 (2025)<\/strong>, 133008. https:\/\/doi.org\/10.1016\/j.biortech.2025.133008<\/a><\/li>\n
  15. \u00a0 15.P Gao, X Ji, C Dong, M Zheng, Zhen Fang<\/strong>, G Bao, Constructing a Cascade Catalytic Strategy with Base Metals for Hydrodeoxygenation of Lignin Derivatives, Fuel<\/u><\/span> (IF 7.5), 402 (2025)<\/strong>, 136055. https:\/\/doi.org\/10.1016\/j.fuel.2025.136055<\/a><\/li>\n
  16. \u00a0 16.GQ Zhu, HY Xu, JY Zhang, GL Xie, Zhen Fang<\/strong>, L Xu, Stainless Steel Catalyzed Pyrolysis of Waste Oil: Biofuel Production, Catalyst Regeneration and Environmental Assessment, Chemical Engineering Journal<\/u> <\/span>(IF 13.2), 521 (2025)<\/strong>, 167020. https:\/\/doi.org\/10.1016\/j.cej.2025.167020<\/a><\/li>\n
  17. \u00a0 17.YT Wang, LY Zhang, LL Kang, YJ Wang, Jun-Guo Li*, H Zhao*, KL Dong, HP Li, X Guo, RL Dong, MM Chen, Zhen Fang*<\/strong>, An Overall Study on Efficient Cr (VI) Adsorbents for Improving of the Application Value of Chlorella Pyrenoidosa, Ecotoxicology and Environmental Safety<\/u><\/span> (IF 6.1), 302 (2025)<\/strong>, 118539. https:\/\/doi.org\/10.1016\/j.ecoenv.2025.118539<\/a><\/li>\n
  18. \u00a0 18.WY Qiu, CY Dong*, JJ Guo, B Xia, L Xu, Zhen Fang<\/strong>*, Enhancing Xylose Fermentation to Maximize Net Energy Gain of Lime-Pretreated Wheat Straw by Delayed Fed-Batch Simultaneous Saccharification and Fermentation, Biomass and Bioenergy<\/u><\/span> (IF 5.8),\u00a0198 (2025)<\/strong>, 107865. https:\/\/doi.org\/10.1016\/j.biombioe.2025.107865<\/a><\/li>\n
  19. \u00a0 19.Y Li, J J Wu, F Liu, W Liu, B Li, Q Zhang, M Wang, H Yang, Zhen Fang<\/strong>, Z Ma*, Promotion Mechanism of Rare-Earth Elements Doping on Performance of CaO\/CeO2<\/sub> Sorbent for High Temperature CO2<\/sub> Capture, Chemical Engineering Journal<\/u> <\/span>(IF 13.2), 5071 (2025)<\/strong>, 160675. https:\/\/doi.org\/10.1016\/j.cej.2025.160675<\/a><\/li>\n
  20. \u00a0 20.L Wang, JJ Guo, Zhen Fang<\/strong>*, Lower Temperature Pretreatment of Wheat Straw for High Production of Fermentable Sugars Using Ball-Milling Combined with Deep Eutectic Solvent, Renewable Energy<\/u><\/span> (IF 9.1),\u00a0241 (2025)<\/strong>, 122240. https:\/\/doi.org\/10.1016\/j.renene.2024.122240<\/a><\/li>\n
  21. \u00a0 21.JJ Guo, Li Wang, YT Wang*, WN Ding*, WW Liu, Zhen Fang<\/strong>*, Dual Lipases Immobilized on Magnetic Hydrophobic Biochar for One-Step Production of Biodiesel in Deep Eutectic Solvent, Fuel<\/u> <\/span>(IF 7.5), 381 (2025)<\/strong>, 133497. https:\/\/doi.org\/10.1016\/j.fuel.2024.133497<\/a><\/li>\n
  22. \u00a0 22.H Wang, JS Chen, ZF Pei, Zhen Fang<\/strong>, S Yang, H Li*, Bio-based Deep Eutectic Solvent of Enhanced Lignin Solubility for Wheat Straw Fractionation and Full-Component Utilization, Industrial Crops and Products<\/u><\/span> (IF 6.2), 223 (2025),<\/strong> 120054. https:\/\/doi.org\/10.1016\/j.indcrop.2024.120054<\/a><\/li>\n
  23. \u00a0 23.FP Wang, LL Kang, YJ Wang YR Wang, YT Wang*, JG Li, LQ Jiang, R Ji, S Chao, JB Zhang, Zhen Fang<\/strong>, Magnetic Biochar Catalyst from Reed Straw and Electric Furnace Dust for Biodiesel Production and Life Cycle Assessment, Renewable Energy<\/u><\/span> (IF 9.1),\u00a0227 (2024)<\/strong>, 120570. https:\/\/doi.org\/10.1016\/j.renene.2024.120570<\/a><\/li>\n
  24. \u00a0 24.XR Meng, S Gao*, NX Liu, PD Wu, Zhen Fang<\/strong>*, Regulating N-doped Biochar with Fe-Mo Heterojunctions as Cathode in Long-Life Zinc-Air Battery, Chemical Engineering Journal<\/u><\/span> (IF 13.2), 500 (2024)<\/strong>, 157463. https:\/\/doi.org\/10.1016\/j.cej.2024.157463<\/a><\/li>\n
  25. \u00a0 25.SR Li, GQ Zhu, C He, LJ Xu*, JA Kozinski, Zhen Fang<\/strong>*, Comprehensive Insights into Synergistic Effects of Cotton Stalk and Polyethylene in Hydrothermal Liquefaction Process, Chemical Engineering Journal<\/u> <\/span>(IF 13.2), 502 (2024),<\/strong> 157845. https:\/\/doi.org\/10.1016\/j.cej.2024.157845<\/a><\/li>\n
  26. \u00a0 26.YL Wang, WJ Guo, W Chen*, GX Xu, GQ Zhu, GL Xie, LJ Xu, CY Dong, S Gao, Y Chen, HP Yang, H Chen, Zhen Fang<\/strong>, Co-production of Porous N-Doped Biochar and Hydrogen-Rich Gas Production from Simultaneous Pyrolysis-Activation-Nitrogen Doping of Biomass: Synergistic Mechanism of KOH and NH3<\/sub>, Renewable Energy<\/u><\/span> (IF 9.1), 229 (2024)<\/strong> 120777. https:\/\/doi.org\/10.1016\/j.renene.2024.120777<\/a><\/li>\n
  27. \u00a0 27.JJ Guo, S Gao, J Yang, H Zhang, YT Wang*, WN Ding*, Zhen Fang*<\/strong>, Biodiesel Production\u00a0via<\/em>Simultaneous Esterification and Transesterification of\u00a0Periplaneta Americana<\/em>\u00a0Oil with Liquid Lipase Eversa\u00ae Transform 2.0, Renewable Energy<\/u><\/span> (IF 9.1),\u00a0 229 (2024)<\/strong>, 120756. https:\/\/doi.org\/10.1016\/j.renene.2024.120756<\/a><\/li>\n
  28. \u00a0 28.Q Dong, CX Gong, GL Xie, GQ Zhu, Zhen\u00a0Fang*<\/strong>, Thermodynamic Modeling of Freeze Pretreatment in the Destruction of Rice Straw Structure Combined with Alkaline-Hydrothermal Method for Enzymatic Hydrolysis,\u00a0Bioresource Technology<\/u><\/span> (IF 9),\u00a0403 (2024)<\/strong>,\u00a0130864. https:\/\/doi.org\/10.1016\/j.biortech.2024.130864<\/a><\/li>\n
  29. \u00a0 29.PD Wu, LY Li, H Li*, Zhen Fang<\/strong>*, Interfacial High-Valence Ni(IV)-Enabled C-H Activation for Photoelectrochemical C-C Bond Cleavage of Lignin to Exclusively Produce Aromatic Carboxylic Acids, Chemical Engineering Journal<\/u> <\/span>(IF 13.2), 2024, 490<\/strong>, 151722. https:\/\/doi.org\/10.1016\/j.cej.2024.151722<\/a><\/li>\n
  30. \u00a0 30.WJ Guo, YR Wang, W Chen, GX Xu, GQ Zhu, GL Xie, L Xu, Zhen Fang<\/strong>, Q Zhang, H Yang, Insight Into the Synergistic Influence of Nitrogen-Doped Biochar and NH3<\/sub> on Selective Production of 4-Vinyl Phenol from Biomass Catalytic Pyrolysis by Coupling Catalyst in-situ<\/em> Regeneration, Industrial Crops and Products<\/u><\/span> (IF 6.2), 214 (2024),<\/strong> 118520. https:\/\/doi.org\/10.1016\/j.indcrop.2024.118520<\/a>.<\/li>\n
  31. \u00a0 31.GQ Zhu, MX Zhu, EZ Wang, CX Gong, YR Wang, WJ Guo, GL Xie, W Chen, C He, LJ Xu*, H Li, Y Zhang, Zhen Fang<\/strong>, Natural Biochar Catalyst: Realizing the Co-Valorization of Waste Cooking Oil into High-Quality Biofuel and Carbon Nanotube Precursor via<\/em> Catalytic Pyrolysis Process, Chemical Engineering Journal<\/u><\/span> (IF 13.2), 486 (2024),<\/strong> 150195. https:\/\/doi.org\/10.1016\/j.cej.2024.150195<\/a>.<\/li>\n
  32. \u00a0 32.GX Xu, S Nanda , JJ Guo, YQ Song, JA Kozinski, AK Dalai, Zhen Fang*<\/strong>, Red Mud Supported Ni-Cu Bimetallic Material for Hydrothermal Production of Hydrogen from Biomass, Industrial Crops and Products<\/u><\/span> (IF 6.2), 212 (2024),<\/strong> 118370. https:\/\/doi.org\/10.1016\/j.indcrop.2024.118370<\/a>.<\/li>\n
  33. \u00a0 33.Y Yang, LZ Chen, ZY Gou, SQ Liu, PD Wu, Zhen Fang*<\/strong>, K Zhang, H Li*, Remote p-d Orbital Hybridization via<\/em> First\/Second-layer Coordination of Fe Single Atoms with Heteroatoms for Enhanced Electrochemical CO2<\/sub>-to-CO Reduction, Journal of Materials Chemistry A<\/u><\/span> (IF 9.5), 2024<\/strong>,12<\/strong>, 8991-9001, https:\/\/doi.org\/10.1039\/D3TA08021H<\/a>.<\/li>\n
  34. \u00a0 34.JJ Guo, YT Wang, Zhen Fang*<\/strong>, Covalent Immobilization of Lipase on Magnetic Biochar for One-Pot Production of Biodiesel from High Acid Value Oil. Bioresource Technology<\/u><\/span> (IF 9), 394 (2024)<\/strong>, 130237. https:\/\/doi.org\/10.1016\/j.biortech.2023.130237<\/a>.<\/li>\n
  35. \u00a0 35.P Cheng, YC Zhang, MF Li, HL Ma, WT Xu, XP Tan, Zhen Fang*,<\/strong> ZX Guo*, LQ Jiang*, Carbonaceous Anodes and Compatible Exoelectrogens in High-Performance Microbial Fuel Cells: A Review, ACS ES&T Engineering<\/u><\/span>, (IF 7.5), 2024, 4,<\/strong> 488-505. https:\/\/doi.org\/10.1021\/acsestengg.3c00512<\/a>.<\/li>\n
  36. \u00a0 36.H Liu, TJ Liu, HW Guo, YJ Wang, R Ji, LL Kang, YT Wang*, X Guo*, JG Li*, LQ Jiang, Zhen Fang<\/strong>*, A Review of the Strategy to Promote Microalgae Value in CO2<\/sub> Conversion-Lipid Enrichment-Biodiesel Production, Journal of Cleaner Production<\/u><\/span> (IF 10), 436 (2024)<\/strong>, 140538. https:\/\/doi.org\/10.1016\/j.jclepro.2023.140538<\/a>. (Highly Cited Paper, top 1%).<\/li>\n
  37. \u00a0 37.GL Xie, GQ Zhu, YF Kang, MX Zhu, QQ Lu, C He, LJ Xu*, Zhen Fang<\/strong>, Valorization of Waste PET: Understanding the Role of Active Ammonia in Facilitating PET Depolymerization and Aromatic Nitrile Formation. Journal of Cleaner Production<\/u> <\/span>(IF 10), 434 (2024)<\/strong>, 140204. https:\/\/doi.org\/10.1016\/j.jclepro.2023.140204<\/a>.<\/li>\n
  38. \u00a0 38.XWJi, GR Bao*, P Gao, J Luo, DQ Chen, Zhen<\/strong>\u00a0<\/strong>Fang<\/strong>, Hydrodeoxygenation of Vanillin to 2-Methoxy-4-Methylphenol over Carbon Dots Supported Pd Catalyst, Molecular Catalysis<\/u> <\/span>(IF 4.9), 553 <\/strong>(2024)<\/strong>, 113722. https:\/\/doi.org\/10.1016\/j.mcat.2023.113722<\/a>.<\/li>\n
  39. \u00a0 39.PYLiu, ZL Wu*, Zhen<\/strong>\u00a0<\/strong>Fang<\/strong>, G\u00a0Cravotto*, Sonolytic Degradation Kinetics and Mechanisms of Antibiotics in Water and Cow Milk, Ultrasonics Sonochemistry<\/u><\/span> (IF 9.7), 99 (2023),<\/strong> 106518, https:\/\/doi.org\/10.1016\/j.ultsonch.2023.106518<\/a>.<\/li>\n
  40. \u00a0 40.GL Xie, GQ Zhu, T Lv, YF Kang, YH Chen, Zhen Fang<\/strong>, LJ Xu*, Sustainable Production of Aromatic-Rich Biofuel via<\/em> Catalytic Co-pyrolysis of Lignin and Waste Polyoxymethylene over Commercial Al2<\/sub>O3<\/sub> Catalyst, The Journal of Analytical and Applied Pyrolysis<\/u><\/span> (IF 6.2), 174 <\/strong>(2023<\/strong>), 106147, https:\/\/doi.org\/10.1016\/j.jaap.2023.106147<\/a>.<\/li>\n
  41. \u00a0 41.JX Zhang, XL Liu, L Wang, Zhen Fang<\/strong>*, Two-stage Process Production of Microbial Lipid by Co-Fermentation of Glucose and N-<\/em>Acetylglucosamine from Food Wastes with Cryptococcus curvatus<\/em>, Bioresource Technology<\/u><\/span> (IF 9), 387<\/strong> (2023<\/strong>), 129685, https:\/\/doi.org\/10,1016\/j.biortech.2023.129685<\/a>.<\/li>\n
  42. \u00a0 42.WJ Cong, J Yang, JG Zhang, Zhen Fang<\/strong>*, ZD Miao. A Green Process for Biodiesel and Hydrogen Coproduction from Waste Oils with a Magnetic Metal-Organic Framework Derived Material. Biomass & Bioenergy<\/u><\/span> (IF 5.8), 175<\/strong> (2023<\/strong>) 106871. https:\/\/doi.org\/10.1016\/j.biombioe.2023.106871<\/a>.<\/li>\n
  43. \u00a0 43.Q Yu, TJ Liu, YN Zeng, YT Wang*, JG Li*, LL Kang, R Ji, FP Wang, XM Wang, B Liu, S Cai, Zhen Fang<\/strong>*. Efficient Lipid Synthesis of Chlorella Pyrenoidosa<\/em> Promoted under Heavy Metals from Electric Arc Furnace Slag, Journal of Cleaner Production<\/u><\/span> (IF 10), 414 (2023)<\/strong> 137648. https:\/\/doi.org\/10.1016\/j.jclepro.2023.137648<\/a>.<\/li>\n
  44. \u00a0 44.PCheng , YC Zhang, NF Ma, LN Wang, LQ Jiang*, Zhen Fang<\/strong>,\u00a0YT\u00a0Wang,\u00a0XP\u00a0Tan, The Parallel Electron Transfer Pathways of Biofilm and Self-Secreted Electron Shuttles in Gram-Positive Strain Rhodococcus Pyridinivorans<\/em> HR-1 Inoculated Microbial Fuel Cell, Bioresource Technology<\/u> <\/span>(IF 9), 369<\/strong> (2023<\/strong>), 128514. https:\/\/doi.org\/10.1016\/j.biortech.2022.128514<\/a>.<\/li>\n
  45. \u00a0 45.J Yang, WJ Cong, YT Wang, ZD Miao, ZY Zhu*, Zhen Fang<\/strong>*, Microwave-Assisted One-step Production of Biodiesel from Waste Cooking Oil by Magnetic Bifunctional SrO-ZnO\/MOF Catalyst, Journal of Cleaner Production<\/u><\/span> (IF 10), 395<\/strong> (2023<\/strong>) 136182. https:\/\/doi.org\/10.1016\/j.jclepro.2023.136182<\/a>. (Highly Cited Paper, top 1%).<\/li>\n
  46. \u00a0 46.XL Liu, Zhen Fang<\/strong>*, XF Tian*, ZD Miao, Impact of Alkalic Salt Coupled Ball Milling Pretreatment of Wheat Straw on Improving Enzymatic Hydrolysis and Energy Efficiency, Fuel<\/u><\/span> (IF 7.5), 340<\/strong> (2023<\/strong>), 127336. https:\/\/doi.org\/10.1016\/j.fuel.2022.127336<\/a>.<\/li>\n
  47. \u00a0 47.PD Wu, LY Li, KP Wang, H Li*, Zhen Fang<\/strong>*, Non-quantum Nanostructure-Enabled Hot Carrier Generation for Enhancive Photoelectrocatalytic Oxidation of Bio-Alcohol in Water Coupled with Hydrogen Evolution, Green Chemistry<\/u> <\/span>(IF 9.2), 25<\/strong> (2023<\/strong>), 2771-2781. https:\/\/doi.org\/10.1039\/D3GC00226H<\/a>.<\/li>\n
  48. \u00a0 48.S Nanda, JA Okolie, R Patel, F Pattnaik, Zhen Fang<\/strong>, AK Dalai*, JA Kozinski, S Naik, Catalytic Hydrothermal Co-Gasification of Canola Meal and Low-Density Polyethylene Using Mixed Metal Oxides for Hydrogen Production, International Journal of Hydrogen Energy<\/u><\/span> (IF 8.3), 47<\/strong> (2022)<\/strong>, 42084-42098. https:\/\/doi.org\/10.1016\/j.ijhydene.2021.08.179<\/a>.<\/li>\n
  49. \u00a0 49.R Ji, TJ Liu, LL Kang, YT Wang, JG Li, FP Wang, Q Yu, XM Wang, H Liu, HW Guo, WL Xu, YN Zeng, Zhen Fang*<\/strong>, A Review of Metallurgical Slag for Efficient Wastewater Treatment: Pretreatment, Performance and Mechanism, Journal of Cleaner Production<\/span> (IF 10)<\/u>, 380 (2022) <\/strong>135076, https:\/\/doi.org\/10.1016\/j.jclepro.2022.135076<\/a>.<\/li>\n
  50. \u00a0 50.P Cheng, LQ Jiang*, R Shan, Zhen Fang<\/strong>, NF Ma*, LW Deng*, YQ Lu, XP Tan, WJ Shen, RR Liu, An Alternative to Vermiculite: Composting on Tropical Islands Using Coral Sand to Enhance Nitrogen Retention during Ventilation, Fermentation<\/span> (IF 3.3), 8<\/strong> (2022<\/strong>), 552. https:\/\/doi.org\/10.3390\/fermentation8100552<\/a>.<\/li>\n
  51. \u00a0 51.LL Kang, YN Zeng, YT Wang,* , JG Li,* , FP Wang, YJ Wang, Q Yu, XM Wang, R Ji, D Gao, Zhen Fang<\/strong>,* Removal of Pollutants from Wastewater Using Coffee Waste as Adsorbent: A Review, Journal of Water Process Engineering<\/span> (IF 6.7), 49<\/strong> (2022<\/strong>) 103178. https:\/\/doi.org\/10.1016\/j.jwpe.2022.103178<\/a>.`<\/li>\n
  52. \u00a0 52.ZX Huang, F Zhang, YB Tang, YD Wen, ZQ Wu, Zhen Fang<\/strong>,* XF Tian,* Rapid Degradation of Rhodamine B through Visible-Photocatalytic Advanced Oxidation Using Self-Degradable Natural Perylene Quinone Derivatives\u2014Hypocrellins, Bioengineering<\/span> (IF 3.7), 9<\/strong> (2022<\/strong>), 307. https:\/\/doi.org\/10.3390\/bioengineering9070307<\/a>.<\/li>\n
  53. \u00a0 53.LJ Xu, GL Xie, XJ Zhou, YC Liu, Zhen Fang<\/strong>*, Catalytic Pyrolysis of Soybean Oil with CaO\/Bio-Char Based Catalyst to Produce High Quality Biofuel, Journal of Renewable Materials<\/u><\/span>, 10<\/strong> (2022<\/strong>), 3107-3118. DOI: 10.32604\/jrm.2022.020691.<\/li>\n
  54. \u00a0 54.JS Huang, YM Jian, H Li*, Zhen Fang<\/strong>, Lignin-Derived Layered 3D Biochar with Controllable Acidity for Enhanced Catalytic Upgrading of Jatropha<\/em> Oil to Biodiesel, Catalysis Today<\/u><\/span> (IF 5.3), 404 <\/strong>(2022<\/strong>) 35-48. https:\/\/doi.org\/10.1016\/j.cattod.2022.04.016<\/a>.<\/li>\n
  55. \u00a0 55.YT Wang, D Gao, J Yang, YN Zeng*, JG Li*, YJ Wang, XM Wang, FP Wang, Q Yu, TJ Liu , S Cai, Zhen Fang*<\/strong>, Highly Stable Heterogeneous Catalysts from Electric Furnace Dust for Biodiesel Production: Optimization, Performance and Reaction Kinetics, Catalysis Today<\/u><\/span> (IF 5.3), 404<\/strong> (2022<\/strong>), 78-92. https:\/\/doi.org\/10.1016\/j.cattod.2021.12.013<\/a>.<\/li>\n
  56. \u00a0 56.YQ Song (Master Student)<\/u>, S Nanda, WJ Cong, J Sun, GH Dong, A Magdziarz, Zhen Fang* <\/strong>(Supervisor), AK Dalai, JA Kozinski, Hydrogen Production from Cotton Stalk over Ni-La Catalysts Supported on Spent Bleaching Clay via<\/em> Hydrothermal Gasification, Industrial Crops and Products <\/u><\/span>(IF 6.2), 186<\/strong> (2022<\/strong>) 115228. https:\/\/doi.org\/10.1016\/j.indcrop.2022.115228<\/a>.<\/li>\n
  57. \u00a0 57.CY Dong, XZ Meng, S-Y Leu, LJ Xu, ZL Wu, G Cravotto, Zhen Fang*, <\/strong>Enhancing a-Etherification of Lignin in Eucalyptus Diol Pretreatment to Improve Lignin Monomer Production, Industrial Crops and Products<\/u><\/span> (IF 6.2), 185 <\/strong>(2022<\/strong>), 115130. https:\/\/doi.org\/10.1016\/j.indcrop.2022.115130<\/a> .<\/li>\n
  58. \u00a0 58.LQ Jiang, JC Luo, F Xu, L Qian, YT Wang, H Li*, Zhen Fang*<\/strong>, High Yield Production of Levoglucosan via<\/em> Catalytic Pyrolysis of Cellulose at Low Temperature, Fuel<\/u><\/span> (IF 7.5), 323 (2022<\/strong>) 124369. https:\/\/doi.org\/10.1016\/j.fuel.2022.124369<\/a>.<\/li>\n
  59. \u00a0 59.YT Wang, XM Wang, D Gao, FP Wang, YN Zeng, JG Li*, LQ Jiang, Q Yu, R Ji, LL Kang, YJ Wang, Zhen Fang*<\/strong>, Efficient Production of Biodiesel at Low Temperature Using Highly Active Bifunctional Na-Fe-Ca Nanocatalyst from Blast Furnace Waste, Fuel<\/u><\/span> (IF 7.5), 322<\/strong> (2022)<\/strong> 124168. https:\/\/doi.org\/10.1016\/j.fuel.2022.124168<\/a>.<\/li>\n
  60. \u00a0 60.XM Wang, YN Zeng, LQ Jiang, YT Wang*, JG Li*, LL Kang, R Ji, D Gao, FP Wang, Q Yu, YJ Wang, Zhen Fang*<\/strong>. Highly stable NaFeO2<\/sub>-Fe3<\/sub>O4<\/sub> Composite Catalyst from Blast Furnace Dust for Efficient Production of Biodiesel at Low Temperature, Industrial Crops and Products<\/u><\/span> (IF 6.2), 182 <\/strong>(2022<\/strong>), 114937. https:\/\/doi.org\/10.1016\/j.indcrop.2022.114937<\/a>.<\/li>\n
  61. \u00a0 61.PD Wu (PhD Student)<\/u>, H Li*, Zhen Fang* <\/strong>(Supervisor), Synergistic Catalysis of Co-Zr\/CNx Bimetallic Nanoparticles Enables Reductive Amination of Bio-Based Levulinic Acid, Advanced Sustainable Systems<\/u><\/span> (IF 6.1), (2022<\/strong>) 2100321. https:\/\/doi.org\/10.1002\/adsu.202100321<\/a>.<\/li>\n
  62. \u00a0 62.XL Liu (PhD Student)<\/u>, CY Dong, SY Leu, Zhen Fang* <\/strong>(Supervisor), ZD Miao, Efficient Saccharification of Wheat Straw Pretreated by Solid Particle-Assisted Ball Milling with Waste Washing Liquor Recycling, Bioresource Technology<\/u> <\/span>(IF 9), 347<\/strong> (2022<\/strong>), 126721. https:\/\/doi.org\/10.1016\/j.biortech.2022.126721<\/a>.<\/li>\n
  63. \u00a0 63.YT Wang, D Gao, YN Zeng*, TJ Liu, S Cai, AM Jia, WJ Cong, FP Wang, Q Yu, XM Wang, JG Li*, Zhen Fang*<\/strong>, Efficient Production of Biodiesel with Electric Furnace Dust Impregnated with Na2<\/sub>CO3<\/sub> Solution, Journal of Cleaner Production<\/u><\/span> (IF 10), 330<\/strong> (2022)<\/strong>, 129772. https:\/\/doi.org\/10.1016\/j.jclepro.2021.129772<\/a>.<\/li>\n
  64. \u00a0 64.LP Li (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), X Kong*, WJ Cong, Production of Jet Fuel Intermediates from Furfural via<\/em> Aldol Condensation over La2<\/sub>O2<\/sub>CO3<\/sub>-Al2<\/sub>O3<\/sub> Catalyst, Molecular Catalysis<\/u> <\/span>(IF 4.9), 515<\/strong> (2021)<\/strong>, 111893. https:\/\/doi.org\/10.1016\/j.mcat.2021.111893<\/a>.<\/li>\n
  65. \u00a0 65.HG Wu, H Li,* Zhen Fang*<\/strong>, Hydrothermal Amination of Biomass to Nitrogenous Chemicals, Green Chemistry<\/u><\/span> (IF 9.2), 23 <\/strong>(2021<\/strong>), 6675-6697 (Critical review, 2021 Green Chemistry Hot Articles). https:\/\/doi.org\/10.1039\/D1GC02505H<\/a>.<\/li>\n
  66. \u00a0 66.YT Wang, WJ Cong, YN Zeng*,YQ Zhang, JL Liang,JGLi, LQ Jiang, Zhen Fang*<\/strong>, Direct Production of Biodiesel via<\/em> Simultaneous Esterification and Transesterification of Inedible Oils Using Calcined Blast Furnace Dust, Renewable Energy<\/u><\/span> (IF 9.1), 175 <\/strong>(2021<\/strong>), 1001-1011. https:\/\/doi.org\/10.1016\/j.renene.2021.05.013<\/a>.<\/li>\n
  67. \u00a0 67.WJ Cong (PhD student)<\/u>, S Nanda, H Li, Zhen Fang* <\/strong>(Supervisor), AK Dalai, JA Kozinski, Metal-Organic Framework-Based Functional Catalytic Materials for Biodiesel Production: A Review, Green Chemistry<\/u><\/span> (IF 9.2), 23 <\/strong>(2021<\/strong>), 2595\u20132618. https:\/\/doi.org\/10.1039\/D1GC00233C<\/a>.<\/li>\n
  68. \u00a0 68.ZY Zhu, YB Liu, WJ Cong,XB Zhao, J Janaun,T Wei, Zhen Fang<\/strong>, Soybean Biodiesel Production Using Synergistic CaO\/Ag Nano Catalyst: Process Optimization, Kinetic Study, and Economic Evaluation, Industrial Crops and Products<\/u><\/span> (IF 5.6), 166 <\/strong>(2021<\/strong>), 113479. https:\/\/doi.org\/10.1016\/j.indcrop.2021.113479<\/a>. (Highly Cited Paper, top 1%).<\/li>\n
  69. \u00a0 69.X Kong (Junior lecturer)<\/u>, XJ Wei (Master student)<\/u>, Zhen Fang*<\/strong>, LP Li, and HW Lei, Production of Liquid Fuel Intermediates from Furfural via<\/em> Aldol Condensation over La2<\/sub>O2<\/sub>CO3<\/sub>-ZnO-Al2<\/sub>O3<\/sub> Catalyst, Catalysis Communications<\/u> <\/span>(IF 4.3), 149<\/strong> (2021<\/strong>), 106207. https:\/\/doi.org\/10.1016\/j.catcom.2020.106207<\/a>.<\/li>\n
  70. \u00a0 70.LJ Xu (Junior lecturer)<\/u>, ZJ He; H Zhang, SH Wu; CY Dong, Zhen Fang*<\/strong>, Production of Aromatic Amines via<\/em> Catalytic Co-pyrolysis of Lignin and Phenol-Formaldehyde Resins with Ammonia over Commercial HZSM-5 Zeolites, Bioresource Technology<\/u> <\/span>(IF 9), 320 <\/strong>(2021<\/strong>), 124252, https:\/\/doi.org\/10.1016\/j.biortech.2020.124252<\/a>.<\/li>\n
  71. \u00a0 71.YF Zhu, X Kong, B Peng, LP Li, Zhen Fang<\/strong>, and YL Zhu, Efficient Cu Catalyst for 5-Hydroxymethylfurfural Hydrogenolysis by Forming Cu-O-Si Bond, Catalysis Science & Technology<\/u><\/span> (IF 4.3), 10<\/strong>, 7323-7330 (2020<\/strong>). https:\/\/doi.org\/10.1039\/D0CY01032D<\/a>.<\/li>\n
  72. \u00a0 72.LJ Xu (Junior lecturer)<\/u>, CC Shi, ZJ He, H Zhang, MY Chen, Zhen Fang*<\/strong>, and Y Zhang*, Recent Advances of Producing Bio-Based N-Containing Compounds via<\/em> Thermo-Chemical Conversion with Ammonia Process, Energy & Fuels<\/u> <\/span>(IF 5.3), 34 <\/strong>(2020<\/strong>), 9, 10441\u201310458 (invited review). https:\/\/doi.org\/10.1021\/acs.energyfuels.0c01993<\/a>.<\/li>\n
  73. \u00a0 73.Zhen Fang*<\/strong>, RL Smith Jr., and H Li, Special Issue on Hydrothermal and Solvothermal Approaches toward Bio-products, The Journal of Supercritical Fluids<\/u><\/span> (IF 4.4), 165 (2020)<\/strong>, 104975. https:\/\/doi.org\/10.1016\/j.supflu.2020.104975<\/a>.<\/li>\n
  74. \u00a0 74.X Kong, YF Zhu, HW Lei, CX Wang, YF Zhao, EG Huo, XN Lin, QF Zhang, M Qian, W Mateo, RG Zou, Zhen Fang<\/strong>, and R Ruan, Synthesis of Graphene-like Carbon from Biomass Pyrolysis and Its Applications, Chemical Engineering Journal<\/u><\/span> (IF 13.2), 399 <\/strong>(2020<\/strong>), 125808. https:\/\/doi.org\/10.1016\/j.cej.2020.125808<\/a>.<\/li>\n
  75. \u00a0 75.S Tang (PhD student)<\/u>, Q Dong (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), WJ Cong (PhD student)<\/u>, H Zhang (PDF)<\/u>, Microbial Lipid Production from Rice Straw Hydrolysates and Recycled Pretreated Glycerol, Bioresource Technology<\/u><\/span> (IF 9), 312<\/strong> (2020<\/strong>), \u200b123580.<\/li>\n
  76. \u00a0 76.YT Wang, Zhen Fang*<\/strong>, Catalytic Biomass to Renewable Biofuels and Biomaterials, Editorial, Catalysts<\/u><\/span> (IF 4), 10 <\/strong>(2020<\/strong>), 480. https:\/\/doi.org\/10.3390\/catal10050480<\/a>.<\/li>\n
  77. \u00a0 77.J Sun (Master student)<\/u>, LJ Xu, GH Dong (Master student)<\/u>, S Nanda, H Li, Zhen Fang* <\/strong>(Supervisor), JA Kozinski, AK Dalai, Subcritical Water Gasification of Lignocellulosic Wastes for Hydrogen Production with Co Modified Ni\/Al2<\/sub>O3<\/sub> Catalysts, The Journal of Supercritical Fluids<\/u><\/span> (IF 4.4), 162 <\/strong>(2020<\/strong>), 104863. https:\/\/doi.org\/10.1016\/j.supflu.2020.104863<\/a>.<\/li>\n
  78. \u00a0 78.WJ Cong (PhD student)<\/u>, YT Wang, H Li, Zhen Fang* <\/strong>(Supervisor), J Sun (Master student)<\/u>, HT Liu (Undergraduate student)<\/u>, JT Liu (Undergraduate student)<\/u>, S. Tang (PhD student)<\/u>, LJ Xu, Direct Production of Biodiesel from Waste Oils with a Strong Solid Base from Alkalized Industrial Clay Ash, Applied Energy<\/u><\/span> (IF 11), 264 <\/strong>(2020<\/strong>), 114735, https:\/\/doi.org\/10.1016\/j.apenergy.2020.114735<\/a>.\u00a0<\/li>\n
  79. \u00a0 79.H Li*, HX Guo, Zhen Fang<\/strong>*, TM Aida, RL Smith Jr*, Cycloamination Strategies for Renewable N-heterocycles, Green Chemistry<\/u><\/span> (IF 9.2), 22 (2020), <\/strong>582-611 (Spotlight Paper, Review). <\/strong>https:\/\/doi.org\/10.1039\/C9GC03655E<\/a>.<\/li>\n
  80. \u00a0 80.S Tang (PhD student)<\/u>, Q Dong (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), WJ Cong (PhD student)<\/u>, ZD Miao (PhD student)<\/u>, High-Concentrated Substrate Enzymatic Hydrolysis of Pretreated Rice Straw with Glycerol and Aluminum Chloride at Low Cellulase Loadings, Bioresource Technology <\/u><\/span>(IF 9), 294 <\/strong>(2019<\/strong>), 122164.<\/li>\n
  81. \u00a0 81.LJ Xu (Junior lecturer)<\/u>, QQ Zhong (Undergraduate student), Q Dong (Master student)<\/u>, LY
    Zhang (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), Co-production of Phenolic Oil and CaO\/Char Deoxidation Catalyst via<\/em> Catalytic Fast Pyrolysis of Phenol-Formaldehyde Resin with Ca(OH)2<\/sub>, The Journal of Analytical and Applied Pyrolysis<\/u><\/span> (IF 6.2), 142<\/strong> (2019<\/strong>, 104663).<\/li>\n
  82. \u00a0 82.LJ Xu (Junior lecturer), LY Zhang (Master student), H Song (PDF), Q Dong (Master student), GH Dong (Master student), X Kong (Junior lecturer), Zhen Fang* <\/strong>(Supervisor), Catalytic Fast Pyrolysis of Polyethylene Terephthalate Waste Plastic for the Selective Production of Terephthalonitrile under Ammonia Atmosphere, Waste Management<\/u><\/span> (IF 7.1), 92 <\/strong>(2019<\/strong>), 97\u2013106.<\/li>\n
  83. \u00a0 83.LJ Xu (Junior lecturer)<\/u>, XW Na (Undergraduate student)<\/u>, LY Zhang (Master student)<\/u>, Q Dong (Master student)<\/u>, GH Dong (Master student)<\/u>, YT Wang, Zhen Fang* <\/strong>(Supervisor), Selective Production of Terephthalonitrile and Benzonitrile via<\/em> Pyrolysis of Polyethylene Terephthalate (PET) with Ammonia Over Ca(OH)2<\/sub>\/Al2<\/sub>O3<\/sub> Catalysts, Catalysts<\/u><\/span> (IF 4), 9 <\/strong>(2019<\/strong>), 436.<\/li>\n
  84. \u00a0 84.S Tang (PhD student)<\/u>, Q Dong (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), ZD Miao (PhD student)<\/u>, Complete Recovery of Cellulose from Rice Straw Pretreated with Ethylene Glycol and Aluminum Chloride for Enzymatic Hydrolysis, Bioresource Technology<\/u><\/span> (IF 9), 284 <\/strong>(2019<\/strong>), 98\u2013104.<\/li>\n
  85. \u00a0 85.LQ Jiang, Zhen Fang<\/strong>*, ZL Zhao*, AQ Zheng, XB Wang, HB Li, Levoglucosan and Its Hydrolysates via<\/em> Fast Pyrolysis of Lignocellulose for Microbial Biofuels: A State-of-the-Art Review, Renewable & Sustainable Energy Reviews<\/u><\/span> (IF 16.3), 105 <\/strong>(2019<\/strong>), 215-229.<\/li>\n
  86. \u00a0 86.H Li (PDF)<\/u>, HX Guo, YQ Su, Y Hiraga, Zhen Fang<\/strong>* (Supervisor), EJM Hensen, M Watanabe*, RL Smith Jr*, N-Formyl-Stabilizing Quasi-Catalytic Species Afford Rapid and Selective Solvent-Free Amination of Biomass-Derived Feedstocks, Nature Communications<\/u><\/span> (IF 15.7), 10<\/strong> (2019<\/strong>), Article number: 699, https:\/\/doi.org\/10.1038\/s41467-019-08577-4<\/a>.<\/li>\n
  87. \u00a0 87.S Nanda, R Rana, HN Hunter, Zhen Fang<\/strong>, AK Dalai, JA Kozinski, Hydrothermal Catalytic Processing of Waste Cooking Oil for Hydrogen-rich Syngas Production, Chemical Engineering Science<\/u><\/span> (IF 4.3), 195 <\/strong>(2019)<\/strong>, 935-945.<\/li>\n
  88. \u00a0 88.YT Wang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), F Zhang (Junior researcher)<\/u>, Esterification of Oleic Acid to Biodiesel Catalyzed by a Highly Acidic Carbonaceous Catalyst, Catalysis Today<\/u> <\/span>(IF 5.3), 319<\/strong> (2019<\/strong>), 172-181 (Highly Cited Paper, top 1%).<\/li>\n
  89. \u00a0 89.H Li (PDF)<\/u>, Y Li, Zhen Fang* <\/strong>(Supervisor), RL Smith Jr, Efficient Catalytic Transfer Hydrogenation of Biomass-Based Furfural to Furfuryl Alcohol with Recycable Hf-Phenylphosphonate Nanohybrids, Catalysis Today<\/u><\/span> (IF 5.3), 319 <\/strong>(2019<\/strong>), 84-92.<\/li>\n
  90. \u00a0 90.X Kong (Junior lecturer)<\/u>, YF Zhu, Zhen Fang* <\/strong>(Supervisor), JA Kozinski, IS Butler, LJ Xu, H Song, XJ Wei, Catalytic Conversion of 5-Hydroxymethylfurfural to Some Value-Added Derivatives, Green Chemistry<\/u> <\/span>(IF 9.2), 20 <\/strong>(2018<\/strong>), 3657-3682\u00a0 (Critical Review. Highly Cited Paper, top 1%).<\/li>\n
  91. \u00a0 91.YT Wang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), XX Yang, YT Yang, J Luo, K Xu, GR Bao, One-step Production of Biodiesel from Jatropha<\/em> Oils with High Acid Value at Low Temperature by Magnetic Acid-Base Amphoteric Nanoparticles, Chemical Engineering Journal<\/u> <\/span>(IF 13.2), 348<\/strong> (2018)<\/strong>,929-939.<\/li>\n
  92. \u00a0 92.CH Zhu (Master student)<\/u>, Zhen Fang* <\/strong>(Supervisor), TC Su (PhD student)<\/u>, XK Li (PhD student)<\/u>, QY Liu, Cellulase Immobilized on Mesoporous Biochar Synthesized by Ionothermal Carbonization of Cellulose, Cellulose<\/u><\/span> (IF 4.8), 25(4)<\/strong> (2018<\/strong>), 2473-2485.<\/li>\n
  93. \u00a0 93.H Li (PDF)<\/u>, TT Yang, Zhen Fang<\/strong>* (Supervisor), Biomass-derived Mesoporous Hf-containing Hybrid for Efficient Meerwein-Ponndorf-Verley Reduction at Low Temperatures, Applied Catalysis B: Environmental<\/u> <\/span>(IF 21.1), 227 <\/strong>(2018<\/strong>), 79\u201389.<\/li>\n
  94. \u00a0 94.X Kong (Junior lecturer)<\/u>, YF Zhu, HY Zheng, YL Zhu*, Zhen Fang* <\/strong>(Supervisor), Inclusion of Zn into Metallic Ni Enables Selective and Effective Synthesis of 2,5-Dimethylfuran from Bio-Derived 5-Hydroxymethylfurfural, ACS Sustainable Chemistry & Engineering<\/u><\/span> (IF 7.3), 5<\/strong> (12)<\/strong> (2017<\/strong>), 11280\u201311289.<\/li>\n
  95. \u00a0 95.UA Amran (PhD student)<\/u>, S Zakaria*, CH Chia, Zhen Fang* <\/strong>(Co-supervisor), MZ Masli, Production of Liquefied Oil Palm Empty Fruit Bunch (EFB) Based Polyols via<\/em> Microwave Heating, Energy & Fuels<\/u> <\/span>(IF 5.3), 31 <\/strong>(2017<\/strong>), 10975\u201310982.<\/li>\n
  96. \u00a0 96.YT Wang (PhD student)<\/u>, Zhen Fang<\/strong>* (Supervisor), XX Yang (Master student), Highly Active and Stable Bifunctional Magnetic Acid for Biodiesel Production, Applied Energy<\/u><\/span> (IF 11), 204 <\/strong>(2017<\/strong>), 702\u2013714.<\/li>\n
  97. \u00a0 97.H Li (PDF)<\/u>, W Zhao, Zhen Fang<\/strong>* (Supervisor), Hydrophobic Pd Nanocatalysts for One-pot and High-yield Production of Liquid Furanic Biofuels at Low Temperatures, Applied Catalysis B: Environmental<\/u><\/span> (IF 21.1), 215 <\/strong>(2017)<\/strong>, 18\u201327.<\/strong><\/li>\n
  98. \u00a0 98.TC Su (PhD student)<\/u>, Zhen Fang<\/strong>* (Supervisor), One-pot Microwave-assisted Hydrolysis of Cellulose and Hemicellulose in Selected Tropical Plant Wastes by NaOH-Freeze Pretreatment, ACS Sustainable Chemistry & Engineering<\/u><\/span> (IF 7.3), 5(6)<\/strong> (2017<\/strong>), 5166-5174.<\/li>\n
  99. \u00a0 99.H Li (PDF)<\/u>, W Zhao, A Riisager, S Saravanamurugan*, Z Wang, Zhen Fang<\/strong>,* (Supervisor) and Song Yang*, Pd-Catalyzed in-situ Domino Process for Mild and Quantitative Production of 2,5-Dimethylfuran Directly from Carbohydrates, Green Chemistry<\/u><\/span> (IF 9.2), 19 <\/strong>(2017<\/strong>), 2101-2106.<\/li>\n
  100. \u00a0 100.F Zhang (Junior researcher)<\/u>, XF Tian, Zhen Fang<\/strong>* (Supervisor), M Shah (PDF)<\/u>, YT Wang (PhD student)<\/u>, W Jiang (undergraduate student)<\/u>, M Yao (undergraduate student)<\/u>, Catalytic Production of Jatropha<\/em> Biodiesel and Hydrogen with Magnetic Carbonaceous Acid and Base Synthesized from Jatropha<\/em> Hulls, Energy Conversion and Management<\/u> <\/span>(IF 10.9), 142<\/strong> (2017<\/strong>), 107-116.<\/li>\n
  101. \u00a0 101.H. Li (PDF), Zhen Fang*<\/strong> (Supervisor), J He, S Yang, Orderly Layered Zr-Benzylphosphonate Nanohybrids for Efficient Acid\/Base-Mediated Bifunctional\/Cascade Catalysis, ChemSusChem<\/u><\/span> (IF 6.6), 10(4) (2017), 681\u2013686.<\/li>\n
  102. \u00a0 102.H Li (PDF)<\/u>, Zhen Fang* <\/strong>(Supervisor), J Luo (Junior researcher), S Yang, Direct Conversion of Biomass Components to the Biofuel Methyl Levulinate Catalyzed by Acid-Base Bifunctional Zirconia-Zeolites, Applied Catalysis B: Environmental<\/u><\/span> (IF 21.1), 200 <\/strong>(2017<\/strong>), 182\u2013191 (Highly Cited Paper, top 1%).<\/li>\n
  103. \u00a0 103.XK Li (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), J Luo (Junior researcher)<\/u>, TC Su (PhD student)<\/u>, Coproduction of Furfural and Easily Hydrolyzable Residue from Sugar Cane Bagasse in the MTHF\/Aqueous Biphasic System: Influence of Acid Species, NaCl Addition, and MTHF, ACS Sustainable Chemistry & Engineering<\/u><\/span> (IF 7.3), 4(10)<\/strong> (2016), <\/strong>5804\u22125813.<\/strong><\/li>\n
  104. \u00a0 104.X<\/u>F Tian (PhD student)<\/u>, L Rehmann, C Xu, Zhen Fang<\/strong>* (Supervisor), Pretreatment of Eastern White Pine (Pinus Strobes L.) for Enzymatic Hydrolysis and Ethanol Production by Organic Electrolyte Solutions, ACS Sustainable Chemistry & Engineering<\/u> <\/span>(IF 7.3), 4(5)<\/strong> (2016<\/strong>), 2822-2829.<\/li>\n
  105. \u00a0 105.F Zhang (PhD student)<\/u>, XH Wu (PhD student)<\/u>, M Yao (undergraduate student)<\/u>, Zhen Fang<\/strong>* (Supervisor), YT Wang<\/u> \uff08<\/u>PhD student<\/u>\uff09<\/u>, Production of Biodiesel and Hydrogen from Plant Oil Catalyzed by Magnetic Carbon-Supported Nickel and Sodium Silicate, Green Chemistry<\/u><\/span> (IF 9.2), 18 <\/strong>(2016<\/strong>), 3302-3314.<\/li>\n
  106. \u00a0 106.M Huang (<\/u>M<\/u>aster student)<\/u>, J Luo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), H Li (PDF)<\/u>, Biodiesel Production Catalyzed by Highly Acidic Carbonaceous Catalysts Synthesized via<\/em> Carbonizing Lignin in Sub- and Super-critical Ethanol, Applied Catalysis B: Environmental<\/u><\/span> (IF 21.1), 190 <\/strong>(2016)<\/strong>, 103\u2013114.<\/li>\n
  107. \u00a0 107.H Li (PDF)<\/u>, Zhen Fang* (<\/strong>Supervisor)<\/strong>, RL Smith Jr, S Yang, Efficient Valorization of Biomass to Biofuels with Bifunctional Solid Catalytic Materials, Progress in Energy and Combustion Science <\/u><\/span>(IF 37), 55 <\/strong>(201<\/strong>6)<\/strong>,<\/strong> 98\u2013194. <\/strong>(Highly Cited Paper, top 1%).<\/li>\n
  108. \u00a0 108.D Jiang (PhD student), Zhen Fang*<\/strong> (Supervisor), SX Chin (PhD student), XF Tian (PhD student), Biohydrogen Production from Hydrolysates of Selected Tropical Biomass Wastes with Clostridium Butyrium, Scientific Reports<\/u><\/strong><\/span> (IF 3.9), 6 (2016), 27205. https:\/\/doi.org\/10.1038\/srep27205<\/a> .<\/li>\n
  109. \u00a0 109.H Li (PhD student)<\/u>, Zhen Fang* <\/strong>(Co-supervisor), S Yang, Direct Conversion of Sugars and Ethyl Levulinate into \u03b3-Valerolactone with Superparamagnetic Acid-Base Bifunctional ZrFeOx Nanocatalysts, ACS Sustainable Chemistry & Engineering<\/u><\/span> (IF 7.3), 4(1)<\/strong> (201<\/strong>6)<\/strong>, 236-246.<\/strong><\/li>\n
  110. \u00a0 110.H Li (PhD student)<\/u>, Zhen Fang* <\/strong>(Co-supervisor), S Yang, Direct Catalytic Transformation of Biomass Derivatives into Biofuel Component g-Valerolactone with Magnetic NiZr Nanoparticles, ChemPlusChem<\/u> <\/span>(IF 2.8), 81<\/strong> (201<\/strong>6<\/strong>), <\/strong>135-142.<\/li>\n
  111. \u00a0 111.TC Su (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), F Zhang (Junior researcher)<\/u>, J Luo (Junior researcher)<\/u>, XK Li (PhD student)<\/u>, Hydrolysis of Selected Tropical Plant Wastes Catalyzed by a Magnetic Carbonaceous Acid with Microwave, Scientific Reports<\/u><\/span> (IF 3.9), 5 <\/strong>(2015<\/strong>), 17538.<\/li>\n
  112. \u00a0 112.Zhen Fang*<\/strong>, How Can We Best Solubilize Lignocellulosic Biomass for Hydrolysis? Biofuels Bioproducts & Biorefining<\/u><\/span> (IF 2.9), 9 <\/strong>(2015<\/strong>), 621\u2013622 (invited editorial).<\/li>\n
  113. \u00a0 113.F Zhang (PhD student)<\/u>, Zhen Fang<\/strong>* (Supervisor), YT Wang (PhD student)<\/u>, Biodiesel Production Direct from High Acid Value Oil with a Novel Magnetic Carbonaceous Acid, Applied Energy<\/u><\/span> (IF 11), 155 <\/strong>(2015<\/strong>), 637\u2013647.<\/li>\n
  114. \u00a0 114.YT Wang (PhD student)<\/u>, Zhen Fang<\/strong>* (Supervisor), F Zhang (PhD student)<\/u>, BJ Xue (Master student)<\/u>, One-step Production of Biodiesel from Oils with High Acid Value by Activated Mg-Al Hydrotalcite Nanoparticles, Bioresource Technology<\/u><\/span> (IF 9), 193 <\/strong>(2015<\/strong>), 84-89.<\/li>\n
  115. \u00a0 115.F Zhang (PhD student)<\/u>, Zhen Fang<\/strong>* (Supervisor), YT Wang (PhD student)<\/u>, Biodiesel Production Directly from Oils with High Acid Value by Magnetic Na2<\/sub>SiO3<\/sub>@Fe3<\/sub>O4<\/sub>\/C Catalyst and Ultrasound, Fuel<\/u> <\/span>(IF 7.5), 150 <\/strong>(2015<\/strong>), 370-377.<\/li>\n
  116. \u00a0 116.SX Chin (PhD student)<\/u>, CH Chia*, S Zakaria, Zhen Fang <\/strong>(Co-supervisor), S Ahmad, Ball Milling Pretreatment and Diluted Acid Hydrolysis of Oil Palm Empty Fruit Bunch (EFB) Fibres for the Production of Levulinic Acid, Journal of the Taiwan Institute of Chemical Engineers<\/u><\/span> (IF 6.3), 52 <\/strong>(2015<\/strong>), 85\u201392.<\/li>\n
  117. \u00a0 117.LQ Jiang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), ZL Zhao, F He, HB Li, 2,3-Butanediol and Acetoin Production from Enzymatic Hydrolysate of Ionic Liquid-pretreated Cellulose by Paenibacillus polymyxa<\/em>, Bioresources<\/u> <\/span>(IF 1.6), 10(1)<\/strong> (2015<\/strong>), 1318-1329.<\/li>\n
  118. \u00a0 118.RL Wang, JC Wang, RH Xu, Zhen Fang<\/strong>, AZ Liu, Oil Production by the Oleaginous Yeast Lipomyces starkeyi<\/em> using Diverse Carbon Sources, Bioresources<\/u><\/span> (IF 1.6), 9(4)<\/strong> (2014<\/strong>), 7027-7040.<\/li>\n
  119. \u00a0 119.F Guo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), Shape-controlled Synthesis of Activated Bio-chars by Surfactant-templated Ionothermal Carbonization in Acidic Ionic Liquid and Activation with Carbon Dioxide, Bioresources<\/u><\/span> (IF 1.6), 9(2)<\/strong> (2014<\/strong>), 3369-3383.<\/li>\n
  120. \u00a0 120.SX Chin (PhD student)<\/u>, CH Chia*, Zhen Fang* <\/strong>(Co-supervisor), S Zakaria, XK Li (PhD student)<\/u>, F Zhang (PhD student)<\/u>, A Kinetic Study on Acid Hydrolysis of Oil Palm Empty Fruit Bunch (EFB) Fibres Using a Microwave Reactor System, Energy & Fuels<\/u><\/span> (IF 5.3), 28(4)<\/strong> (2014<\/strong>), 2589-2597.<\/li>\n
  121. \u00a0 121.BJ Xue (Master student)<\/u>, J Luo (Junior researcher)<\/u>, F Zhang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), Biodiesel Production from Soybean and Jatropha<\/em> Oils by Magnetic CaFe2<\/sub>O4<\/sub>-Ca2<\/sub>Fe2<\/sub>O5<\/sub>-Based Catalyst, Energy<\/u><\/span> (IF 9.4), 68 <\/strong>(2014<\/strong>), 584-591.<\/li>\n
  122. \u00a0 122.J Luo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), RL Smith Jr, Ultrasound-enhanced Conversion of Biomass to Biofuels, Progress in Energy and Combustion Science<\/u><\/span> (IF 37), 41 <\/strong>(2014<\/strong>), 56-93. (Highly Cited Paper, top 1%).<\/li>\n
  123. \u00a0 123.SP Fan (PhD student)<\/u>, LQ Jiang (PhD student)<\/u>, CH Chia*, Zhen Fang* <\/strong>(Co-supervisor), S Zakaria, KL Chee, High Yield Production of Sugars from Deproteinated Palm Kernel Cake under Microwave Radiation via<\/em> Dilute Sulfuric Acid Hydrolysis, Bioresource Technology<\/u><\/span> (IF 9), 153 <\/strong>(2014<\/strong>), 69-78.<\/li>\n
  124. \u00a0 124.YD Long (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), TC Su (PhD student)<\/u>, Q Yang, Co-production of Biodiesel and Hydrogen from Rapeseed and Jatropha<\/em> Oils with Sodium Silicate and Ni Catalysts, Applied Energy<\/u><\/span> (IF 11), 113 <\/strong>(2014<\/strong>), 1819-1825.<\/li>\n
  125. \u00a0 125.LQ Jiang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), XK Li (PhD student)<\/u>, J Luo (Junior researcher)<\/u>, SP Fan (PhD student)<\/u>, Combination of Dilute Acid and Ionic Liquid Pretreatments of Sugarcane Bagasse for Enzymatic Saccharification, Process Biochemistry<\/u><\/span> (IF 4), 48 <\/strong>(2013<\/strong>), 1942-1946.<\/li>\n
  126. \u00a0 126.LQ Jiang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), XK Li<\/u> (PhD student)<\/u>, J Luo (Junior researcher)<\/u>, Production of 2,3-Butanediol from Cellulose and Jatropha<\/em> Hulls after Ionic Liquid Pretreatment and Dilute-Acid Hydrolysis, AMB Express<\/u><\/span> (IF 3.7), 3<\/strong>:48 (2013<\/strong>).<\/li>\n
  127. \u00a0 127.F Zhang (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), Hydrolysis of Cellulose to Glucose at the Low Temperature of 423 K with CaFe2<\/sub>O4<\/sub>-based Solid Catalyst, Bioresource Technology<\/u><\/span> (IF 9), 124 <\/strong>(2012<\/strong>), 440-445.<\/li>\n
  128. \u00a0 128.YD Long (PhD student)<\/u>, Zhen Fang*<\/strong>(Supervisor), Hydrothermal Conversion of Glycerol to Chemicals and Hydrogen: Review and Perspective, Biofuels Bioproducts & Biorefining<\/u><\/span> (IF 2.9), 6 <\/strong>(2012<\/strong>), 686-702.<\/li>\n
  129. \u00a0 129.F Guo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), TJ Zhou (<\/u>Undergraduate student)<\/u>, Conversion of Fructose and Glucose into 5-Hydroxymethylfurfural with Lignin-Derived Carbonaceous Catalyst under Microwave Irradiation in Dimethyl Sulfoxide-Ionic Liquid Mixtures, Bioresource Technology<\/u><\/span> (IF 9), 112 <\/strong>(2012<\/strong>), 313-318.<\/li>\n
  130. \u00a0 130.LQ<\/u> Jiang (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), F Guo (Junior researcher)<\/u>, L<\/u>B Yang (Undergraduate student)<\/u>, Production of 2,3-Butanediol from Acid Hydrolysates of Jatropha<\/em> Hulls with Klebsiella Oxytoca<\/em>, Bioresource Technology<\/u><\/span> (IF 9), 107 <\/strong>(2012<\/strong>), 405-410.<\/li>\n
  131. \u00a0 131.XF Tian (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), F Guo (Junior researcher)<\/u>, Impact and Prospective of Fungal Pretreatment of Lignocellulosic Biomass for Enzymatic Hydrolysis, Biofuels Bioproducts & Biorefining<\/u> <\/span>(IF 2.9), 6 <\/strong>(2012<\/strong>), 335-350 (invited review).<\/li>\n
  132. \u00a0 132.F Guo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), C Xu, RL Smith Jr, Solid Acid Mediated Hydrolysis of Biomass for Producing Biofuels, Progress in Energy and Combustion Science<\/u><\/span> (IF 37), 38 <\/strong>(2012<\/strong>), 672-690. (Invited review, Highly Cited Paper, top 1%).<\/li>\n
  133. \u00a0 133.CY Yang, Zhen Fang (co-first-author)*<\/strong>, B Li, YF Long, Review and Prospects of Jatropha<\/em> Biodiesel Industry in China, Renewable & Sustainable Energy Reviews<\/u><\/span> (IF 16.3), 16 <\/strong>(2012<\/strong>), 2178-2190.<\/li>\n
  134. \u00a0 134.F Guo, NN Wei, ZL Xiu, Zhen Fang<\/strong>, Transesterification Mechanism of Soybean Oil to Biodiesel Catalyzed by Calcined Sodium Silicate, Fuel<\/u><\/span> (IF 7.5), 93 <\/strong>(2012<\/strong>), 468-472.<\/li>\n
  135. \u00a0 135.XF Tian (PhD student)<\/u>, Zhen Fang* <\/strong>(Supervisor), D Jiang (PhD student)<\/u>, XY Sun <\/u>(PhD student)<\/u>, Pretreatment of Microcrystalline Cellulose in Organic Electrolyte Solutions for Enzymatic Hydrolysis, Biotechnology for biofuels<\/u><\/span> (IF 6.1), 4<\/strong>:53 (201<\/strong>1<\/strong>).<\/li>\n
  136. \u00a0 136.FL Pua <\/u>(PhD student)<\/u>, Zhen Fang* <\/strong>(Co-supervisor), S Zakaria*, CH Chia, F Guo (Junior researcher)<\/u>, Direct Production of Biodiesel from High-Acid Value Jatropha<\/em> Oil with Solid Acid Catalyst Derived from Lignin, Biotechnology for biofuels<\/u><\/span> (IF 6.1), 4<\/strong>:56 (201<\/strong>1<\/strong>).<\/li>\n
  137. \u00a0 137.Zhen Fang* <\/strong>(Co-supervisor), F Zhang (Master student)<\/u>, HY Zeng, F Guo (Junior researcher)<\/u>, Production of Glucose by Hydrolysis of Cellulose at 423 K in the Presence of Activated Hydrotalcite Nanoparticles, Bioresource Technology<\/span><\/u> (IF 9), 102 <\/strong>(2011<\/strong>), 8017-8021.<\/li>\n
  138. \u00a0 138.YD Long (PhD student)<\/u>, F Guo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), XF Tian (PhD student)<\/u>, LQ Jiang (PhD student)<\/u>, F Zhang (Master student)<\/u>, Production of Biodiesel and Lactic Acid from Rapeseed Oil Using Sodium Silicate as Catalyst, Bioresource Technology<\/u><\/span> (IF 9), 102 <\/strong>(2011<\/strong>), 6884-6886.<\/li>\n
  139. \u00a0 139.F Guo (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), XF Tian (PhD student)<\/u>, YD Long (PhD student)<\/u>, LQ Jiang (PhD student)<\/u>, One-step Production of Biodiesel from High-acid Value Jatropha<\/em> Oil in Ionic Liquids, Bioresource Technology<\/u> <\/span>(IF 9), 102 <\/strong>(2011<\/strong>), 6469-6472.<\/li>\n
  140. \u00a0 140.Zhen Fang*<\/strong>, Noncatalytic Fast Hydrolysis of Wood, Bioresource Technology<\/u><\/span> (IF 9), 102 <\/strong>(2011<\/strong>), 3587-3590.<\/li>\n
  141. \u00a0 141.X Deng (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), YH Liu (Undergraduate student)<\/u>, CL Yu, Production of Biodiesel from Jatropha<\/em> Oil Catalyzed by Nanosized Solid Basic Catalyst, Energy<\/u><\/span> (IF 9.4), 36 <\/strong>(2011<\/strong>), 777-784. (Highly Cited Paper, top 1%).<\/li>\n
  142. \u00a0 142.RL Smith, Jr, Zhen Fang<\/strong>, Properties and Phase Equilibria of Fluid Mixtures as the Basis for Developing Green Chemical Processes, Fluid Phase Equilibria<\/u><\/span> (IF 2.7), 302 <\/strong>(2011<\/strong>), 65-73 (invited review).<\/li>\n
  143. \u00a0 143.Zhen Fang*<\/strong>, RL Smith Jr, JA Kozinski, T Minowa, K Arai, Reaction of D-Glucose in Water at High Temperatures (410 o<\/sup>C) and Pressures (180 MPa) for the Production of Dyes and Nano-particles, The Journal of Supercritical Fluids<\/u> <\/span>(IF 4.4), 56 <\/strong>(2011<\/strong>), 41-47.<\/li>\n
  144. \u00a0 144.X Deng (Junior researcher)<\/u>, Zhen Fang* <\/strong>(Supervisor), YH Liu (Undergraduate student)<\/u>, Ultrasonic Transesterification of Jatropha Curcas <\/em>L. Oil to Biodiesel by a Two-step Process, Energy Conversion and Management<\/span><\/u> (IF 10.9), 51 <\/strong>(2010<\/strong>), 2802-2807.<\/li>\n<\/ol>\n