吴志强

男， 西安交通化工学院工业催化研究所， 教授/研究员/教授级高工或同等级别

学习/工作经历

2005/09~2009/07：西安交通大学，能源动力系统及自动化、经济学，双学士
2009/09~2015/03：西安交通大学，动力工程及工程热物理，工学博士(硕博连读)
2015/04~2018/02：西安交通大学，化工学院工业催化所，讲师
2016/08~2017/08：英属哥伦比亚大学 (UBC)，化学工程与生物工程系，访问学者
2018/02~2023/01：西安交通大学，化工学院工业催化所，副教授，博导
2023/01~至今 ：西安交通大学，化工学院工业催化所，教授，博导，西安交通大学青拔A

研究领域和兴趣

生物质化学链转化制备绿氢/富油煤地下原位热解提油固碳

主要业绩

主要从事生物质与煤炭等碳氢资源高效清洁转化研究，在AIChE. J、Chem. Eng. Sci、Ind. Eng. Chem. Res.、Chem. Eng. J等期刊以第一/独立通讯作者发表论文40余篇，6篇一作论文入选ESI高被引论文；主持自然科学基金面上/青年项目、重点研发计划子课题等国家/省部基金和企业项目15项；申请国家发明专利71件，授权51件。任中国化工学会工程热化学专委会青年委员、中国生态经济学会工业生态经济与技术专委会理事、Int. J. Coal. Sci. Technol副主编等。入选西安交通大学青年拔尖人才计划（A类）、陕西省青年科技新星、陕西高校青年杰出人才、王宽诚青年学者、陕西省科协青年托举计划，获侯德榜化工科学技术奖青年奖。

代表成果

1. Zhiqiang Wu, Shuzhong Wang, Jun Zhao, Lin Chen, & Haiyu Meng. Synergistic effect on thermal behavior during co-pyrolysis of lignocellulosic biomass model components blend with bituminous coal. Bioresource technology 169, 220–228 (2014).
2. Zhiqiang Wu, Shuzhong Wang, Jun Zhao, Lin Chen, & Haiyu Meng. Thermal behavior and char structure evolution of bituminous coal blends with edible fungi residue during co-pyrolysis. Energy & Fuels 28, 1792–1801 (2014).
3. Haiyu Meng, Shuzhong Wang, Lin Chen, Zhiqiang Wu, & Jun Zhao. Investigation on synergistic effects and char morphology during co-pyrolysis of poly (vinyl chloride) blended with different rank coals from Northern China. Energy & Fuels 29, 6645–6655 (2015).
4. Haiyu Meng, Shuzhong Wang, Lin Chen, Zhiqiang Wu, & Jun Zhao. Thermal behavior and the evolution of char structure during co-pyrolysis of platanus wood blends with different rank coals from northern China. Fuel 158, 602–611 (2015).
5. Zhiqiang Wu, Shuzhong Wang, Jun Zhao, Lin Chen, & Haiyu Meng. Product Distribution during Co-pyrolysis of Bituminous Coal and Lignocellulosic Biomass Major Components in a Drop-Tube Furnace. Energy & Fuels 29, 4168–4180 (2015).
6. Haiyu Meng, Shuzhong Wang, Lin Chen, Zhiqiang Wu, & Jun Zhao. Study on product distributions and char morphology during rapid co-pyrolysis of platanus wood and lignite in a drop tube fixed-bed reactor. Bioresource technology 209, 273–281 (2016).
7. Zhiqiang Wu, Shuzhong Wang, Jun Zhao, Lin Chen, & Haiyu Meng. Thermochemical behavior and char morphology analysis of blended bituminous coal and lignocellulosic biomass model compound co-pyrolysis: effects of cellulose and carboxymethylcellulose sodium. Fuel 171, 65–73 (2016).
8. Lin Chen, Shuzhong Wang, Haiyu Meng, Zhiqiang Wu, & Jun Zhao. Synergistic effect on thermal behavior and char morphology analysis during co-pyrolysis of paulownia wood blended with different plastics waste. Applied Thermal Engineering 111, 834–846 (2017).
9. Zhao Jun, Wang Shuzhong, Wu Zhiqiang, Meng Haiyu, & Chen Lin. Hydrogen-rich syngas produced from the co-pyrolysis of municipal solid waste and wheat straw. International Journal of Hydrogen Energy 42, 19701–19708 (2017).
10. Zhiqiang Wu et al. Performance evaluation on co-gasification of bituminous coal and wheat straw in entrained flow gasification system. International Journal of Hydrogen Energy 42, 18884–18893 (2017).
11. Zhiqiang Wu et al. Physico-chemical properties and gasification reactivity of co-pyrolysis char from different rank of coal blended with lignocellulosic biomass: Effects of the cellulose. Bioresource Technology 235, 256–264 (2017).
12. Zhiqiang Wu et al. Physicochemical structure and gasification reactivity of co-pyrolysis char from two kinds of coal blended with lignocellulosic biomass: Effects of the carboxymethylcellulose sodium. Applied Energy 207, 96–106 (2017).
13. Zhiqiang Wu et al. Morphology and microstructure of co-pyrolysis char from bituminous coal blended with lignocellulosic biomass: Effects of cellulose, hemicellulose and lignin. Applied Thermal Engineering 116, 24–32 (2017).
14. Zhiqiang Wu, Wangcai Yang, Xueyu Tian, & Bolun Yang. Synergistic effects from co-pyrolysis of low-rank coal and model components of microalgae biomass. Energy Conversion and Management 135, 212–225 (2017).
15. Qiang Hu et al. Thermal behavior and reaction kinetics analysis of pyrolysis and subsequent in-situ gasification of torrefied biomass pellets. Energy Conversion and Management 161, 205–214 (2018).
16. Zhiqiang Wu, Wangcai Yang, & Bolun Yang. Thermal characteristics and surface morphology of char during co-pyrolysis of low-rank coal blended with microalgal biomass: Effects of nannochloropsis and Chlorella. Bioresource technology 249, 501–509 (2018).
17. Zhiqiang Wu, Wangcai Yang, Yaowu Li, & Bolun Yang. Co-pyrolysis behavior of microalgae biomass and low-quality coal: Products distributions, char-surface morphology, and synergistic effects. Bioresource technology 255, 238–245 (2018).
18. Zhiqiang Wu, Wangcai Yang, Yaowu Li, Bo Zhang, & Bolun Yang. On-line analysis on the interaction between organic compounds from co-pyrolysis of microalgae and low-rank coal: Thermal behavior and kinetic characteristics. Bioresource technology 268, 672–676 (2018).
19. Donghai Xu et al. Catalytic supercritical water gasification of aqueous phase directly derived from microalgae hydrothermal liquefaction. International Journal of Hydrogen Energy 44, 26181–26192 (2019).
20. Donghai Xu et al. Hydrothermal upgrading of water-insoluble algal biocrude over γ-Al2O3 supported multi-metallic catalysts. Journal of analytical and applied pyrolysis 140, 188–194 (2019).
21. Donghai Xu et al. Heterogeneous catalytic effects on the characteristics of water-soluble and water-insoluble biocrudes in chlorella hydrothermal liquefaction. Applied Energy 243, 165–174 (2019).
22. Donghai Xu et al. Co-hydrothermal liquefaction of microalgae and sewage sludge in subcritical water: Ash effects on bio-oil production. Renewable Energy 138, 1143–1151 (2019).
23. Qiang Hu et al. Experimental and modeling study of potassium catalyzed gasification of woody char pellet with CO2. Energy 171, 678–688 (2019).
24. Zhao Jiang, Xiang Gong, Bin Wang, Zhiqiang Wu, & Tao Fang. A experimental study on the dehydrogenation performance of dodecahydro-N-ethylcarbazole on M/TiO2 catalysts. International Journal of Hydrogen Energy 44, 2951–2959 (2019).
25. Zhao Jiang, Zhiqiang Wu, Tao Fang, & Chunhai Yi. Enhancement CH bond activation of methane via doping Pd, Pt, Rh and Ni on Cu (1 1 1) surface: A DFT study. Chemical Physics Letters 715, 323–329 (2019).
26. Zhiqiang Wu et al. Products distribution and kinetic analysis on gaseous products during fast pyrolysis of two kinds of biomass pellet. Fuel 249, 8–14 (2019).
27. Zhiqiang Wu et al. Chemical looping gasification of lignocellulosic biomass with iron-based oxygen carrier: Products distribution and kinetic analysis on gaseous products from cellulose. Fuel Processing Technology 193, 361–371 (2019).
28. Zhiqiang Wu et al. Energy Recovery of Furnace Slag from Steel Industrial and Thermochemical Conversion of Lignocellulosic Biomass: Thermal Behavior and Kinetic Analysis on Cellulose under Fast Pyrolysis Conditions. Energy & Fuels 34, 1111–1118 (2019).
29. Zhiqiang Wu, Chen Ma, Zhao Jiang, & Zhengyuan Luo. Structure evolution and gasification characteristic analysis on co-pyrolysis char from lignocellulosic biomass and two ranks of coal: Effect of wheat straw. Fuel 239, 180–190 (2019).
30. Zhiqiang Wu, Yaowu Li, Bo Zhang, Wangcai Yang, & Bolun Yang. Co-pyrolysis behavior of microalgae biomass and low-rank coal: kinetic analysis of the main volatile products. Bioresource technology 271, 202–209 (2019).
31. Zhiqiang Wu, Yaowu Li, Donghai Xu, & Haiyu Meng. Co-pyrolysis of lignocellulosic biomass with low-quality coal: Optimal design and synergistic effect from gaseous products distribution. Fuel 236, 43–54 (2019).
32. Bo Zhang, Zhiqiang Wu, Jie Zhang, Wei Guo, & Bolun Yang. Chemical Looping with Oxygen Uncoupling of the Lignocellulosic Biomass Main Model Compound: Product Distribution and Kinetic Analysis on Lignin. Energy & Fuels 34, 10968–10979 (2020).
33. Long Cheng et al. Tar elimination from biomass gasification syngas with bauxite residue derived catalysts and gasification char. Applied Energy 258, 114088 (2020).
34. Mengjiao Tan et al. Pelletization of Camellia oleifera Abel. shell after storage: Energy consumption and pellet properties. Fuel Processing Technology 201, 106337 (2020).
35. Wenbin Hao, Peng Luo, Zhiqiang Wu, Guoxing Sun, & Yongli Mi. Feasibility of Pine Bark Pellets and Their Pyrolyzed Biochar Pellets as Fuel Sources in Molten Hydroxide Direct Carbon Fuel Cells. Energy & Fuels 34, 16756–16764 (2020).
36. Zhiqiang Wu et al. Synergistic effects from co-pyrolysis of lignocellulosic biomass main component with low-rank coal: Online and offline analysis on products distribution and kinetic characteristics. Applied Energy 276, 115461 (2020).
37. Bo Zhang et al. Effect of torrefaction pretreatment on the fast pyrolysis behavior of biomass: Product distribution and kinetic analysis on spruce-pin-fir sawdust. Journal of Analytical and Applied Pyrolysis 158, 105259 (2021).
38. Bo Zhang et al. Chemical looping gasification of maceral from low-rank coal: Products distribution and kinetic analysis on vitrinite. Chinese Journal of Chemical Engineering 36, 233–241 (2021).
39. Guanyu Jiang et al. Thermochemical methods for the treatment of municipal sludge. Journal of Cleaner Production 311, 127811 (2021).
40. Jun Zhao et al. Hydrogen-rich syngas produced from co-gasification of municipal solid waste and wheat straw in an oxygen-enriched air fluidized bed. International Journal of Hydrogen Energy 46, 18051–18063 (2021).
41. Meiquan Li et al. Effects of granulator structure and cooperating mode with slag tube on the centrifugal granulation characteristics of molten slag. Applied Thermal Engineering 193, 117026 (2021).
42. Peng Zhang, Bolun Yang, Heping Ma, & Zhiqiang Wu. Graphene modified porous organic polymer supported phosphotungstic acid catalyst for alkylation desulfurization. Fuel 293, 120438 (2021).
43. Rongjiang Zhang et al. Effect of torrefaction pretreatment on biomass chemical looping gasification (BCLG) characteristics: Gaseous products distribution and kinetic analysis. Energy Conversion and Management 237, 114100 (2021).
44. Song Wu, Bolun Yang, Bo Zhang, Wei Guo, & Zhiqiang Wu. Chemical looping conversion characteristics and kinetic behavior of main components in microalgae biomass: Glycine and starch. Journal of Analytical and Applied Pyrolysis 156, 105179 (2021).
45. Wei Guo et al. Liquid chemical looping gasification of biomass: Thermodynamic analysis on cellulose. Chinese Journal of Chemical Engineering 37, 79–88 (2021).
46. Wei Guo et al. Thermodynamics and kinetics analysis from liquid chemical looping gasification of lignin with bismuth-based oxygen carrier. Fuel Processing Technology 219, 106888 (2021).
47. Wenbin Hao, Peng Luo, Zhiqiang Wu, Yongli Mi, & Zhan Gao. The effect of biomass pyrolysis temperature on the performance of biochar-fed molten hydroxide direct carbon fuel cells. Biomass and Bioenergy 150, 106122 (2021).
48. Yingjie Fan et al. Synergistic effects from fast co-pyrolysis of lignin with low-rank coal: On-line analysis of products distribution and fractal analysis on co-pyrolysis char. Journal of the Energy Institute 97, 152–160 (2021).
49. Yingjie Fan et al. Process intensification on suspension pyrolysis of ultra-fine low-rank pulverized coal via conveyor bed on pilot scale: Distribution and characteristics of products. Fuel 286, 119341 (2021).
50. Yunan Liu et al. Mechanism of sulfamic acid modified biochar for highly efficient removal of tetracycline. Journal of Analytical and Applied Pyrolysis 158, 105247 (2021).
51. Zhiqiang Wu et al. Synergistic effects from co-pyrolysis of lignocellulosic biomass with low-rank coal: A perspective based on the interaction of organic components. Fuel 306, 121648 (2021).
52. Bo Zhang, Yunchang Li, Bolun Yang, Jianxuan Shang, & Zhiqiang Wu. Controlling the reaction microenvironments through an embedding strategy to strengthen the chemical looping reforming of methane based on decoupling process. Chemical Engineering Journal 446, 137061 (2022).
53. Ge Liu, Xiangyang Mao, Bolun Yang, Jianxuan Shang, & Zhiqiang Wu. Research progress on chemical looping reforming of macromolecular components of volatiles from biomass pyrolysis based on decoupling strategy. Fuel Processing Technology 235, 107375 (2022).
54. Gen Liu et al. Performance Evaluation of Torrefaction Coupled with a Chemical Looping Gasification Process under Autothermal Conditions: Flexible Syngas Production from Biomass. Energy & Fuels (2022).
55. Guangju Ma et al. Technology of free calcium oxide (f-CaO) digestion in steel slag by origin adjusting under the vision of carbon neutralization. Energy 2004, 2965 (2022).
56. Haiyu Meng et al. Physico-Chemical Structure and Gasification Performance of Co-Pyrolytic Char Produced by the Pyrolysis of Polyvinyl Chloride Blends with Two Rank Coals. ACS omega 7, 32280–32291 (2022).
57. Haiyu Meng et al. Co-pyrolysis of platanus wood and bituminous coal: Product distributions, char pore analysis and synergistic effects. Journal of Analytical and Applied Pyrolysis 167, 105703 (2022).
58. Jing Bai, Bo Zhang, Bolun Yang, Jianxuan Shang, & Zhiqiang Wu. Preparation of three-dimensional interconnected graphene/ionic liquid composites to enhanced thermal conductivities for battery thermal management. Journal of Cleaner Production 370, 133572 (2022).
59. Jun Zhao et al. Investigation on Unsteady Phase-Change Heat Transfer Characteristics of Centrifugal Granulated Particles. Heat Transfer Engineering 43, 806–817 (2022).
60. Mingyan Ma et al. Co-pyrolysis re-use of sludge and biomass waste: Development, Kinetics, Synergistic mechanism and Industrialization. Journal of Analytical and Applied Pyrolysis 105746 (2022) doi:10.1016/j.jaap.2022.105746.
61. Ningwen Xu et al. Flow Characteristics of the Liquid Film During Centrifugal Granulation of Liquid Slag on the Surface of Rotary Cup. Journal of Sustainable Metallurgy 8, 632–645 (2022).
62. Peng-sen Wang, Bo-lun Yang, Emayavaramban Perumal, & Zhi-qiang Wu. Mechanism and kinetics of 1‐phenyl‐1, 2‐ethanediol cleavage catalyzed by Cu/Beta zeolite. International Journal of Chemical Kinetics 54, 391–399 (2022).
63. Wei Guo et al. Thermal behavior and kinetics analysis from liquid chemical looping gasification of cellulose with bismuth-based and antimony-based oxygen carriers. Fuel 321, 124047 (2022).
64. Xiangyang Mao et al. Chemical looping reforming of toluene via Fe2O3@ SBA-15 based on controlling reaction microenvironments. Fuel 326, 125024 (2022).
65. Rongjiang Zhang et al. Effects of oxidative torrefaction conditions on the biomass liquid chemical looping reaction from the perspective of thermal behavior and kinetic analysis. Fuel 331, 125924 (2023).

*以上信息由高级会员个人更新和维护。