低碳洁净能源实验室

姓       名：李文志                                        性别：男

出生年月：1976年3月                                  籍贯：安徽蒙城

学       位：工学博士                                     职称：教授/博导

学术兼职：《太阳能学报》和《太阳能》杂志编委；

                 《林产化学与工业》编委；

                《中国林业百科全书》生物质能源及材料卷编委；

                  中国可再生能源学会第十届理事会理事； 

                  中国农学会秸秆资源综合利用分会副主任委员；

                  中国能源学会专家委员会委员；

                  安徽省院士专家联合会常务理事

                  Energies期刊Guest Editor；

                  航天科工二院二零六所“高端智能装备概念验证中心”专家。

一、联系方式

单位：中国科学技术大学热科学和能源工程系

地址：安徽省合肥市金寨路96号

邮编：230026

电话：0551-63600786

传真：0551-63600786

电子邮件：liwenzhi@ustc.edu.cn

二、工作简历

2008,4~2010,6   中国科学技术大学热科学和能源工程系   讲师；

2010,7~ 2018,6   中国科学技术大学热科学和能源工程系   副教授;

2018,7~ 中国科学技术大学热科学和能源工程系   教授;

2012,1~2013,2    北卡罗莱纳州立大学访问学者（博士后研究）；

2013~2016年间分别在杜克、瑞典皇家理学院、麻省大学和布朗大学做短期学术交流

三、研究方向

生物质绿色高效分离

生物质制备特种燃料

低浓度甲烷制备液体燃料

四、获奖或荣誉

1、2023年度安徽省科技进步二等奖；

2、2024年度日内瓦国际发明展金奖；

3、2024年度安徽省秸秆综合利用和畜禽废弃物资源化利用工作优秀个人；

4、2021年荣获国家林业和草原局/中国林学会梁希林业科学技术二等奖；

5、2020年荣获江苏省能源研究会能源科学技术进步特等奖；

6、荣获2016年度王宽诚育才奖；

7、2015年荣获安徽省杰出青年基金资助；

8、荣获2012年度中科院广州能源所奖教学金；

9、荣获2009年度张宗植青年教师奖；

五、代表性论著

论文：

[01] Wen-zhi Li, Yong-jie Yan, Ting-chen Li, et al. Preparation of hydrogen via catalytic gasification of residues from biomass hydrolysis with a novel high strength catalyst . Energy & Fuels, 2008, 22(2):1233-1238.

[02] Wen-zhi Li, Jie Xu,Yong-jie Yan, et al. Studies of Monosaccharide Production through Lignocellulosic Waste Hydrolysis Using Double Acids. Energy & Fuels, 2008, 22(3), 2015-2021.

[03] Feng Huang, Wenzhi Li*, Qiang Lu, Xifeng Zhu. Homogeneous Catalytic Hydrogenation of Bio-oil and Related Model Aldehydes with RuCl₂ (PPh₃)₃. Chemical Engineering & Technology, 2010, 33(12):2082~2088.

[04] Mingjian Zhang, Wenzhi Li*, Shuai Zu, et al. Catalytic Hydrogenation for Bio-oil Upgrading by a Supported NiMoB Amorphous Alloy. Chemical Engineering & Technology, 2013, 36(12):2108~2166.

[05] Shuai Zu, Wen-zhi Li*, Mingjian Zhang, et al. Pretreatment of corn stover for sugar production using dilute hydrochloric acid followed by lime. Bioresource Technology, 2014, 152: 364-370.

[06] Wei Huo, Wenzhi Li*, Minjian Zhang, et al. Effective C–O Bond Cleavage of Lignin b-O-4 Model Compounds: A New RuHCl(CO)(PPh3)3/KOH Catalytic System. Catal. Lett. 2014, 144(7): 1159-1163.

[07] Zhiping Xu, Wenzhi Li*, Zhijie Du, et al. Conversion of Corn Stalk into Furfural Using a Novel Heterogeneous Strong Acid Catalyst in γ-Valerolactone. Bioresource Technology, 2015, 198:764-771.

[08] Zhijie Du, Wenzhi Li*, Zhiping Xu, et al. Characterization of C₆₀/Bi₂TiO₄F₂ as a Potential Visible Spectrum Photocatalyst for the Depolymerization of Lignin. Journal of Wood Chemistry and Technology. 2016, 36(5):365-376.

[09] D. Pi, W. Z. Li*, Q. Z. Lin, et al. Highly Active and Thermally Stable Pd@SiO2 Core-Shell Supported Catalyst for Methane Catalytic Combustion. Energy Technology. 2016, 4:943-949.

[10] Tingwei Zhang, Wenzhi Li*, Zhiping Xu, et al. Catalytic Conversion of Xylose and Corn Stalk into Furfural over Carbon Solid Acid Catalyst in γ-Valerolactone. Bioresource Technology. 2016, 209:108-114.

[11] Qifu HUANG, Wenzhi LI*, Qizhao LIN, et al. A review of significant factors in the synthesis of hetero-structured dumbbell-like nanoparticles. Chinese Journal of Catalysis. 2016, 37(5):681-691.

[12] Qiyu Liu, Wenzhi Li*, Qiaozhi Ma, et al. Pretreatment of corn stover for sugar production using a two-stage dilute acid followed by wet-milling pretreatment process. Bioresource Technology. 2016, 211:435-442.

[13]Wenzhi Li, Qiyu Liu, Qiaozhi Ma, et al. A two-stage pretreatment process using dilute hydrochloric acid followed by Fenton oxidation to improve sugar recovery from corn stover. Bioresource Technology. 2016, 219(11): 753-756.

[14] Tingwei Zhang, Wei Fan, Wenzhi Li*, et al. One-pot Conversion of Carbohydrates into HMF Using Heterogeneous Lewis and Brønsted Acid Catalysts. Energy Technology. 2017, 5(5):747-755.

[15]Shao chunyu, Wenzhi Li*, lin qizhao, et al. Low temperature complete combustion of lean methane over cobalt nickel oxide catalysts. Energy Technology. 2017, 5:604-610.

[16] Qiaozhi Ma, Qiyu Liu, Wenzhi Li*, et al. Catalytic depolymerization of lignin for liquefied fuel at mild condition by rare earth metals loading on CNT. Fuel Processing Technology. 2017, 161(6):220-225.

[17] Chao Hu, Wenzhi Li*, Qizhao Lin, et al. Effects of ferrocene on flame temperature, formation of soot particles and growth of polycyclic aromatic hydrocarbons. Journal of the Energy Institute. 2017, 90(6):893-901.

[18] Jindong Wang, Wenzhi Li*, Huizhen Wang, et al. Liquefaction of kraft lignin by hydrocracking with simultaneous use of a novel dual acid-base catalyst and a hydrogenation catalyst. Bioresource Technology. 2017, 243(7): 100-106.

[19] Mingxue Su, Wenzhi Li*, Tingwei Zhang, et al. Production of liquid fuel intermediates from furfural via aldol condensation over Lewis acid zeolite catalysts. Catalysis Science & Technology. 2017, 7:3555-3561.

[20]Wenzhi Li, Yuanshuai Zhu, Yijuan Lu, et al. Enhanced furfural production from raw corn stover employing a novel heterogenous acid catalyst. Bioresource Technology. 2017, 245: 258-265.

[21] Qifu Huang, Wenzhi Li*, Qizhao Lin, et al. Catalytic performance of Pd-NiCo₂O₄/SiO₂ in lean methane combustion at low temperature. Journal of the Energy Institute. 2018, 91:733-742.

[22] Lele Jin, Wenzhi Li*, Qiying Liu, et al. Liquefaction of kraft lignin over the composite catalyst HTaMoO₆ and Rh/C in dioxane-water system. Fuel Processing Technology. 2018, 178(9):62-70.

[23] Yanyan Lei, Wenzhi Li*, Qingchuan Liu, et al, Fengyu Li. Typical crystal face effects of different morphology ceria on the activity ofPd/CeO₂ catalysts for lean methane combustion. Fuel. 2018, 233:10-20.

[24] Qifu Huang, Wenzhi Li*, Yanyan Lei, et al. Catalytic performance of novel hierarchical porous flower-like NiCo₂O₄ supported Pd in lean methane oxidation. Catalysis Letters. 2018, 148(9):2799-2811.

[25] Feng Huang, Wenzhi Li*, Qingchuan Liu, et al. Sulfonated tobacco stem carbon as efficient catalyst for dehydration of C6 carbohydrate to 5-hydroxymethylfurfural in γ-valerolactone/water. Fuel Processing Technology. 2018, 181:294-303.

[26] Tingwei Zhang, Wenzhi Li*, Shengxin An, et al. Efficient transformation of corn stover to furfural using p-Hydroxybenzenesulfonic acid-formaldehyde resin solid acid. Bioresource Technology. 2018, 264:261-267.

[27]Wenzhi Li, Xiaomeng Dou, Chaofeng Zhu, et al. Production of liquefied fuel from depolymerization of kraft lignin over anovel modified nickel/H-beta catalyst. Bioresource Technology. 2018, 269:346-354.

[28]Wenzhi Li, Mingxue Su, Tingwei Zhang, et al. Production of liquid fuel intermediates from furfural via aldol condensation over potassium-promoted Sn-MFI catalyst. Fuel. 2019, 237: 1281-1290.

[29] Shengxin An, Wenzhi Li*, Qiyu Liu, et al. Combined dilute hydrochloric acid and alkaline wet oxidation pretreatmentto improve sugar recovery of corn stover. Bioresource Technology. 2019, 271:283-288.

[30] Tingwei Zhang, Wenzhi Li*, HaoshengXin, et al. Production of HMF from glucose using an Al³⁺ promoted acidic phenol-formaldehyde resin catalyst. Catalysis Communications. 2019, 124: 56-61.

[31] Chaofeng Zhu, Xiaomeng Dou, Wenzhi Li*, et al. Efficient depolymerization of Kraft lignin to liquid fuels over an amorphous titanium-zirconium mixed oxide supported partially reduced nickel-cobalt catalyst. Bioresource Technology. 2019, 284(7): 293 - 301.  

[32] Tingwei Zhang, Yijuan Lu, Wenzhi Li*,et al. One-pot production of g-valerolactone from furfuralusing Zr-graphitic carbon nitride/H-β composite. International Journal of Hydrogen Energy.2019, 44(29):14527-14535.

[33] Lele Jin, Wenzhi Li*, Qiying Liu, Longlong Ma, Song Li, Yang Liu, Baikai Zhang, Qi Zhang. Catalytic Conversion of Cellulose to C5/C6 alkanes over Ir-VOx/SO2 combined with HZSM-5 in n-dodecane/water system. Fuel Processing Technolog. 2019, 196(12):106161-106171.

[34] Qiyu Liu, Qiaozhi Ma, Sanket Sabnis, Weiqing Zheng, Dionisios G. Vlachosd, Wei Fan, Wenzhi Li*, and Longlong Ma. Production of High-Yield Short-Chain Oligomers or Glucose from Cellulose via Selective Hydrolysis in Molten Salt Hydrates and Separation. Green Chemistry. 2019, 21:5030-5038.

[35] Mingxue Su, Wenzhi Li*, Qiaozhi Ma, et al. Efficient synthesis of liquid fuel intermediates from furfural and levulinic acid via aldol condensation over hierarchical MFI zeolite catalyst. Energy Fuels. 2019, 33:12518-12526.

[36] Qingqing Li, Haiyong Wang, Zhipeng Tian, Yujing Weng, Chenguang Wang, Jianru Ma, Chaofeng Zhu, Wenzhi Li*, Qiying Liu* and Longlong Ma. Selective oxidation of 5-hydroxymethylfurfural to2,5-furandicarboxylic acid over Au/CeO2catalysts:the morphology effect of CeO2. Catal. Sci. Technol., 2019, 9:1570-1580. 

[37] Xiaomeng Dou, Xiao Jiang, Wenzhi Li*, et al. Highly efficient conversion of Kraft lignin into liquid fuels with a Co-Zn-beta zeolite catalyst. Applied Catalysis B: Environmental. 2020, 268(7): 118429-118445.

[38] Shengnan Guan, Qifu Huang, Jianru Ma, Wenzhi Li*, et al. HCHO Removal by MnO2(x)-CeO2: Influence of the Synergistic Effect on the Catalytic Activity. Ind. Eng. Chem. Res. 2020, 59(2):596-608.

[39] Baikai Zhang, Wenzhi Li*, Xiaomeng Dou, et al. Catalytic depolymerization of Kraft lignin to produce liquid fuels via Ni-Sn metallic oxides catalysts. Sustainable Energy & Fuels. 2020, 4:1332-1339.

[40] Qiuyan Duan, Wenzhi Li*, Chenghua Zhang, et al. Atomically dispersed palladium-based catalysts via constructing spatial structure with high performance for lean methane combustion. Journal of Materials Chemistry A.2020, 8:7395 -7404.

[41] Kun Chen, Wenzhi Li*, Zean Zhou, et al. Hydroxyl groups attached to Co²⁺ on the surface of Co3O4: A promising structure for propane catalytic oxidation. Catalysis Science & Technology. 2020, 10: 2573-2582.

[42] Shengxin An, Wenzhi Li*, Fengyang Xue, et al. Effect of removing hemicellulose and lignin synchronously under mild conditions on enzymatic hydrolysis of corn stover. Fuel Processing Technology. 2020, 204:106407-106413.

[43] Cunshuo Li, Wenzhi Li*, Kun Chen, et al. Highly active Pd catalysts supported on surface-modified cobalt-nickel mixed oxides for low temperature oxidation of lean methane. Fuel. 2020, 279:118372-118380.

[44] Mingwei Wu, Wenzhi Li*, Ajibola T. Ogunbiyi, Ge Guo, Fengyang Xue, Kun Chen, Baikai Zhang. Highly Active and Stable Palladium Catalysts Supported onSurface-modified Ceria Nanowires for Lean MethaneCombustion. ChemCatChem. 2020, 12:1-11.

[45] Wenzhi Li, Tao Yang, Mingxue Su, Yang Liu, Catalytic Conversion of Glucose to 5 Hydroxymethylfurfural and Furfural by a Phosphate Doped SnO2 Catalyst in γ Valerolactone Water System. Catalysis Letters. 2020, 150:3304-3313.

[46] Cunshuo Li, Wenzhi Li*, Kun Chen, Ajibola T. Ogunbiyi, Zean Zhou,* Fengyang Xue, and Liang Yuan. Palladium Nanoparticles Supported on Surface-Modified MetalOxides for Catalytic Oxidation of Lean Methane. ACS Appl. Nano Mater. 2020, 3(12):12130-12138.

[47] Xiaomeng Dou, Wenzhi Li*, Chaofeng Zhu. Catalytic hydrotreatment of Kraft lignin into liquid fuels over porous ZnCoOx nanoplates. Fuel.2021, 283: 118801-118808.

[48] Tingwei Zhang; Wei, Haiying; Ling, Rongxin; Jin*, Yongcan; Xiao, Huining; Li, Wenzhi*. Efficient production of 5-hydroxymethylfurfural from glucose over silica-tin oxide composite catalysts. Microporous and Mesoporous Materials. 2021, 31:110717-110726.

[49] Ge Guo, Wenzhi Li*, Xiaomeng Dou, Ajibola T. Ogunbiyi, Tauseef Ahmed, Baikai Zhang, Mingwei Wu. Hydroconversion of Kraft lignin for biofuels production using bifunctional rhenium-molybdenum supported zeolitic imidazolate framework nanocatalyst. Bioresource Technology. 2021, 321:124443-124453.

[50] Tao Yang, Wenzhi Li*, Shengxin An. Efficient catalytic conversion of corn stover to furfural and 5-hydromethylfurfural using glucosamine hydrochloride derived carbon solid acid in Ƴ-valerolactone. Industrial crops and products. 2021, 161(3):113173-113182.

[51]Xiaomeng Dou, Wenzhi Li*, Chaofeng Zhu, Xiao Jiang. Catalytic waste Kraft lignin hydrodeoxygenation to liquid fuels over a hollow Ni-Fe catalyst. Applied Catalysis B: Environmental. 2021, 287:119975-119976.

[52] Tao Yang,Wenzhi Li*, Ajibola T. Ogunbiyi. The effect of Br- and alkali in enhancing the oxidation of furfural to maleic acid with hydrogen peroxide. Molecular Catalysis. 2021, 504(3):111488-111493.

[53]Xia Zhang, Wenzhi Li*, Zean Zhou, Kun Chen, Mingwei Wu Liang Yuan. High dispersed Pd supported on CeO2 (1 0 0) for CO oxidation at low temperature. Molecular Catalysis. 2021, 508: 111580-111587.

[54] Mingwei Wu, Wenzhi Li*, Xia Zhang, Fengyang Xue, Tao Yang, Liang Yuan. Penta-coordinated Al³⁺ Stabilized Defect-Rich Ceria on Al₂O₃ Supported Palladium Catalysts for Lean Methane Oxidation. ChemCatChem. 2021, 13:3490-3500.  

[55] Tao Yang, Wenzhi Li*, Mingxue Su, et al. Production of furfural from xylose catalyzed by a novel calcium gluconate derived carbon solid acid in 1,4-dioxane. New Journal of Chemistry. 2020, 44:7968-7975.

[56] Baikai Zhang, Wenzhi Li*, Tingwei Zhang, Xu Li, Ajibola T. Ogunbiyi, Kun Chen, Changcheng Shen. Study on the removal and depolymerization of lignin from corn stover through the synergistic effect of Brønsted acid, Lewis acid and hydrogenation sites. Fuel. 2021, 305:121509-121518.

[57] Ge Guo, Dong Chen, Tauseef Ahmed, Xiaomeng Dou, Kun Chen, Wenzhi Li*. Catalytic depolymerization of Kraft lignin towards liquid fuels over bifunctional molybdenum oxide based supported catalyst. Fuel. 2021, 306:121599-121610.

[58] Changcheng Shen, Wenzhi Li*, Baikai Zhang, Fengyang Xue, Xiaomeng Dou, Xia Zhang, Yihang Jiang. Valorization of Lignin in Native Corn Stover via Fractionation-hydrogenolysis Process over Cobalt-Supported Catalyst without External Hydrogen. Molecular Catalysis. 2021, 514:111832-111842.

[59] Tao Yang, Dong Chen, Wenzhi Li*, Hao Zhang. Efficient conversion of corn stover to 5-hydroxymethylfurfural and furfuralusing a novel acidic resin catalyst in water-1, 4-dioxane system. Molecular Catalysis. 2021, 515:111920-111928.

[60] Baikai Zhang, Wenzhi Li*, Xu Li. The selectivity depolymerization of corn stover lignin via nickel-doped tinphosphate catalyst in the absence of hydrogen. Industrial Crops & Products. 2021, 174:114211-114220.

[61] Kun Chen, Wenzhi Li*,Xinzhe Li, Ajibola T. Ogunbiyi, and Liang Yuan. Irregularly Shaped NiO Nanostructures for Catalytic Lean Methane Combustion. ACS Appl. Nano Mater. 2021, 4, 5404-5412.

[62] Xiangqian Wei, Wenzhi Li*, Qiying Liu, Weitao Sun, Siwei Liu, Song Li, Haoyang Wei, Longlong Ma. Pore-scale investigation on multiphase reactive transport for the conversion of levulinic acid to γ-valerolactone with Ru/C catalyst. Chemical Engineering Journal. 2022, 427：130917-130929.  

[63] Tingwei Zhang, Haiying Wei, Junlong Gao, Sihong Chen, Yongcan Jin, Chao Deng,Shufang Wu, Huining Xiao, Wenzhi Li*. Synthesis of sulfonated hierarchical carbons and theirs application on theproduction of furfural from wheat straw. Molecular Catalysis. 2022, 517:112034-112044.

[64] Baikai Zhang, Wenzhi Li*, Xu Li. Selective production of lignin-derived monomers from corn stover bytuning the acid and hydrogenation sites of aluminum phosphate catalysts. Industrial Crops & Products. 2022, 178:114608-114616.

[65] Yihang Jiang, Wenzhi Li*, Kun Chen, Xia Zhang, Changcheng Shen, Liang Yuan. A rod-like Co3O4 with high efficiency and large specific surface area for lean methane catalytic oxidation. Molecular catalysis. 2022, 522:112229-112236.

[66] Chen Zhu, Shengnan Guan, Wenzhi Li*, Ajibola T. Ogunbiyi, Kun Chen, Qi Zhang. Degradation of formaldehyde over MnO2/CeO2 hollow spheres: Elucidating the influence of carbon spheres self-sacrificing template. ACS Omega. 2021, 6:35404−35415.

[67] Kun Chen, Wenzhi Li*, Ge Guo, Chen Zhu, Wenjian Wu, and Liang Yuan. Nickel Hydroxide Nanosheets Prepared by a Direct Manual Grinding Strategy for High-Efficiency Catalytic Combustion of Methane. ACS omega.2022, 7:8536-8546.

[68] Chen, Kun; Li, Wenzhi*; Zhu, Chen; Yuan, Liang. Construction of Hollow Cobalt Tetroxide Nanocages through the Metal Salt Bifunctional Etching Strategy for Catalytic Oxidation of Propane at Ultra-High Space Velocity. ACS Applied Nano Materials. 2022, 5:6575-6584.

[69] Bingyue Tang, Wenzhi Li*, Xia Zhang, Baikai Zhang, Hao Zhang, Cunshuo Li. Depolymerization of Kraft lignin to liquid fuels with MoS₂ derived oxygen-vacancy-enriched MoO₃ in a hydrogen-donor solvent system. Fuel. 2022, 324: 124674-124683.

[70] Xia Zhang, Wenzhi Li*, Jindong Wang, Baikai Zhang, Ge Guo, Changcheng Shen, Yihang Jiang. Depolymerization of kraft lignin into liquid fuels over a WO3 modified acid-base coupled hydrogenation catalyst. Fuel. 2022, 323:124428-124437.

[71] Cunshuo Li, Bingyue Tang, Ajibola T. Ogunbiyi, Songquan Tang, Wenzhi Li, Qiang Lu, Liang Yuan. The Effects of Facet-Dependent Palladium-Titania Interactions on the Activity of Pd/Rutile Catalysts for Lean Methane Oxidation. Molecular Catalysis. 2022, 528:112475-112485.

[72] Weitao Sun, Xiangqian Wei,* Wenzhi Li,* Xinghua Zhang, Haoyang Wei, Siwei Liu, and Longlong Ma*.Numerical Studies on Cellulose Hydrolysis in Organic -Liquid- Solid Phase Systems with a Liquid Membrane Catalysis Model. ACS Omega. 2022, 7:2286-2303.

[73] Cunshuo Li, Songquan Tang, Bingyue Tang, Wenzhi Li*, Liang Yuan. The effects of alkali metal ions on the physiochemical and catalyticproperties of Pd/NiAlOx catalysts for lean methane oxidation. Molecular Catalysis. 2022, 530:112614-112626.

[74] Mingwei Wu, Meng Miao, Wenzhi Li*, Lulu Zhang, Liang Yuan. Metal-organic Framework-derived One-Dimensional Pd@CeO₂ Catalysts with Enhanced Activity for Methane Oxidation. Fuel. 2023, 331:125575-125584.

[75]Li, Cunshuo; Tang, Bingyue; Li, Wenzhi*; Lu, Qiang; Yuan, Liang. Palladium Nanoparticles Encapsulated in Surface-Defected SBA-15 for Lean Methane Oxidation. ACS APPLIED NANO MATERIALS. 2022, 5:13055-13068.

[76] Chen Zhu, Ge Guo, Wenzhi Li*, Mingwei Wu, Yihang Jiang, Wenjian Wu, Hao Zhang. Direct Catalytic Oxidation of Low-Concentration Methane to Methanol in One Step on Ni-Promoted BiOCl Catalysts. ACS Omega, 2023, 8(12): 11220–11232.

[77] Jingting Jin, Wenzhi Li*, Lulu Zhang, Leyu Zhu, Liqun Wang, Zheng Zhou. CuxOy nanoparticles and Cu–OH motif decorated ZSM-5 for selective methane oxidation to methyl oxygenates. Journal of Colloid And Interface Science. 2023, 645:964-973.

[78] Leyu Zhu, Wenzhi Li*, Hao Zhang, Xia Zhang, Jingting Jin, Mingwei Wu. Bimetallic Ruthenium- and Zinc-Doped Beta zeolite for efficiently depolymerizing Kraft lignin. Fuel. 2023, 349: 128766-128776.

[79] Cunshuo Li, Bingyue Tang, Xiangguang Fu, Taimin Zheng, Liqun Wang,Hao Zhang,Wenzhi Li*，Liang Yuan. Highly active siO2-supported palladium nanoparticles prepared by amodified ammonia evaporation method for lean methane oxidation. Molecular Catalysis. 2023, 549:113522-113532.

[80] Yan Fu, Cunshuo Li, Shengxin An, Wenzhi Li*, Liang Yuan. Cu and Zn Bimetallic Co-Modified H-MOR Catalyst for DirectOxidation of Low-Concentration Methane to Methanol. ACS Omega. 2023, 8:27179-27189.

[81]Cunshuo Li, Bingyue Tang, Yu Bai, Wenzhi Li*, Qiang Lu, Liang Yuan. Facet-dependently interfacial hybridization stabilized trivalent ceriumspecies and related application in the catalytic oxidation of lean methane. Journal of Environmental Chemical Engineering.  2023, 11:111282-111290.

[82] Taimin Zheng, Wenzhi Li*, Cunshuo Li, Shengxin An, Yihang Jiang, Liang Yuan. Single-step methane to methanol over lanthanum cerium oxide: The crucialrole of surface reactive oxygen and carbonate species. Molecular Catalysis. 2023, 551:113623-113634.

[83]Xia Zhang, Yihang Jiang,Wenzhi Li*, Leyu Zhu, Liqun Wang. Production of liquid fuels via catalytic transfer hydrogenation promotinglignin depolymerization on modifed Y zeolite: Formic acid as a continuoushydrogen source. Energy Conversion and Management. 2024, 302:118144-118154.

[84] Zheng Zhou, Meng Miao, Wenzhi Li*, Jingting Jin, Liqun Wang, Lulu Zhang,Liang Yuan. Synergistic effect of Cu and Fe on g-C3N4 for selective oxidation of methane to C1 products. Molecular Catalysis. 2024, 562:114237-114247.

[85] Leyu Zhu, Wenzhi Li*, Xia Zhang, Liqun Wang, Jingting Jin, ZhengZhou, Lulu Zhang. Fully upgrade bamboo biomass into three multifunctionalproducts through biphasic γ-valerolactone and aqueousphosphoric acid pretreatment. Bioresource Technology. 2024, 406:130946-130955.

[86] Xia Zhang, Wenzhi Li*, Yihang Jiang, Leyu Zhu, Liqun Wang. Valorization of waste lignin: Efficient and steady production of liquid fuels. Industrial Crops & Products. 2024, 220:119400-119410.

[87]Liqun Wang, Jingting Jin, Wenzhi Li*, Cunshuo Li, Leyu Zhu, Zheng Zhou, Lulu Zhang, Xia Zhang, Liang Yuan. Highly Selective Catalytic Oxidation of Methane to Methanol using Cu-Pd/Anatase. Energy & Environmental Science. 2024, 17:9122–9133.

[88] Xuanlan Xie, Chang Li*, Zhiheng Lu, Yishuang Wang, Wenqiang Yang, Mingqiang Chen*, Wenzhi Li*. Noble metal modified copper-exchanged mordenite zeolite (Cu-ex-MOR) catalysts for catalyzing the methane efficient gas-phase synthesis methanol. Energy, 2024, 300: 131595-131608.

[89] Yihang Jiang, Wenzhi Li*, Xia Zhang, Liang Yuan. The impact of Cu distribution in Cu/SAPO-34 catalyst on the continuousdirect conversion of methane to methanol. Microporous and Mesoporous Materials. 2025, 391:113607-113616.

[90] Songquan Tang, Wenzhi Li*, Jingting Jin, Xin Zhang, Zilong Shen, Yunfan Gui. Lean methane catalytic combustion using Pd/ZSM-5 catalysts prepared by ammonia evaporation method. Molecular Catalysis. 2025, 579:115092-115101.

授权发明专利：

[01]李文志,朱锡锋,等.均相催化精制生物油的方法. 发明专利号：200910091731.0

[02]李文志, 商丽敏, 等. 一种精制生物油的方法. 发明专利号：201210055550.4

[03] 李文志, 杜志杰, 等. 一种复合催化剂、其制备方法和木质素的解聚方法. 发明专利号：201510490715.4

[04] 李文志, 徐志平, 等. 一种呋喃类化合物的制备方法. 发明专利号：201510582626.2

[05] 李文志, 李明灏，等. 一种丁二酸的制备方法. 发明专利号：201510618176.8

[06]李文志、孙继亮、等. 一种木质素纤维素类生物质连续水解反应器. 实用新型专利号: 201620390305.2

[07] 李文志、王晋东、等. 一种催化解聚木质素的方法. 发明专利号：201710373585.5

[08] 李文志、晋乐乐、等. 一种催化解聚木质素的方法. 发明专利号：201711347661.1

[09] 李文志、关圣楠、等. 一种低温脱除甲醛的方法. 发明专利号：201810140663.1

[10] 李文志、黄锋、等. 一种生物质碳基固体酸催化剂及其制备方法和应用. 发明专利号：201810783996.6

[11] 李文志、窦晓萌、等. 一种木质素的解聚方法.国际发明专利：PCT/CN2018/095946

[12] 李文志、杨涛. 一种催化糠醛氧化制备马来酸的催化剂及其应用. 发明专利号：201811367627.5

[13] 李文志、杨涛、等. 催化糠醛氧化制备马来酸的催化剂及其制备方法和应用. 发明专利号：201811372436.8

[14] 李文志、祝超锋、等. 一种催化解聚木质素的方法. 发明专利号：201910132448.1

[15] 李文志、段秋艳、等. 一种单原子钯基催化剂及其制备方法以及应用. 发明专利号：201910841606.0

[16] 李文志、李存朔、洪紫薇. 一种二氧化铪复合材料、其制备方法及其应用. 发明专利号：202010706183.4

[17] 李文志、吴明伟、洪紫薇. 一种催化燃烧催化剂、其制备方法及应用. 发明专利号：202011270440.0

[18] 李文志、薛凤洋. 一种基于酸性乙二醇溶液高效脱除木质素的方法. 发明专利号：202011472482.2

[19] 李文志、鲁怡娟、朱远帅、马巧智、刘启予、王晋东. 一种糠醛制备γ-戊内酯的催化剂、其制备方法及γ-戊内酯的制备方法. 发明专利号：201810385635.6

[20] 李文志、吴明伟、袁亮. 一种表面硅修饰的钴-镍符合氧化物催化剂及其制备方法、催化煤层气氧化制甲醇的方法. 发明专利号：202110270895.0

[21] 李文志、杜志杰、安胜欣.一种木质素分离系统及其方法；发明专利号：202111459309.3

[22] Wenzhi Li, Tao Yang, Mingxue Su, Jianru Ma. Catalyst for catalytic oxidation of furfural to prepare maleic acid and application thereof. US 11,235,314 B2

[23] 李文志、唐冰月、李存朔. 一种催化解聚木质素的方法. 发明专利号：202210913767.8

[24] 李文志、陈锟、李存朔、袁亮. 一种花型催化剂、其制备方法及应用. 发明专利号：202110318819.2

[25] 李文志、李存朔、唐冰月. 一种抗水催化剂及其制备方法和应用. 发明专利号：202310407803.8

[26] 李文志、李存朔、王立群. 一种钯基催化剂在催化氧化煤层气制取甲醇反应中的应用以及制取甲醇的方法. 发明专利号：2023111283840

六、主持的代表性项目

1. 国家863计划“分级均相催化加氢耦合催化裂解精制生物油的研究”，项目负责人，2009,6~2011,5；

2. 国家自然科学基金“亚临界甲醇体系中生物油分级均相催化提质的机理研究”，项目负责人，2010,1~2012,12；

3. 科技部863计划“生物质先进裂解制取生物燃油关键技术--生物燃油降酸提质研究”，子课题负责人，2012,1~2016,12；

4. 科学院重点部署项目“木质纤维素类生物质水相催化制取燃料与全成分转化利用”，子课题负责人，2013,1~2015,12；

5. 国家自然科学基金“可见光耦合热催化解聚木质素低聚物精制生物油的研究”，项目负责人，2012,1~2015,12；

6. 国家973计划“生物水热解聚及解聚过程中大分子结构解析”，中科大方面课题负责人，2012,1~2016,12；

7. 安徽省杰出青年科学基金“生物质双相体系解聚制备液体燃料和化学品的机理研究”， 项目负责人，2015,7~2018,6

8. 国家科技支撑计划“生物质热化学定向转化关键技术”，负责人，2015,4~ 2019,3

9. 国家自然科学基金“金属/稀土介孔分子筛催化解聚木质素的机理研究”，项目负责人，2017,1~2020,12；

10. 安徽省国际合作项目“农作物秸秆催化转化制备丁二酸化物的联合研发”，项目负责人，2015,10 ~ 2018,10；

11. 中科院战略性先导科技专项（A类）“木质纤维素水相解聚与5-羟甲基糠醛高效制备关键技术”，任务负责人，2018,4 ~ 2023,4；

12. 国家重点研发计划“木质纤维素绿色分离及高效解聚研究”，子课题负责人，2019,4~ 2023,3；

13. 国家自然科学基金“多级孔类分子筛基双金属协同解聚木质素的机理研究”，项目负责人，2020,1 ~ 2023,12。

14. 合肥综合性国家科学中心 “低浓度煤层气低温部分氧化制甲醇技术及示范”，项目负责人，2021,6~2025,6；

15、安徽省科技重大专项“分子筛基Ni/Co双金属协同催化低浓度瓦斯制甲醇技术及示范”，项目负责人，2020,10~2023,9；

16、国家重点研发计划“秸秆三素高效分离技术及化工原料创制”，课题负责人，2023,12 ~ 2027,12。