祝晓琳（副教授）

  姓    名：

祝晓琳

  职    称：

副教授

  导师类别：

　硕士生导师

  系    室：

　化学工程系

  研究领域：

　工业催化、石油化工

  电子邮箱：

zhuxiaolin@upc.edu.cn, upczhuxl@163.com

  联系电话：

15275266591

◎教育背景

2005.9-2009.7， 中国石油大学（华东）， 化学工程与工艺， 工学学士

2009.9-2014.7， 中国石油大学（华东）， 化学工程与技术， 博士研究生

◎工作经历

2014.8-2016.6， 清华大学， 化学工程系， 博士后

2016.7-2016.12， 中国石油大学（华东）， 化学工程学院， 讲师

2017.1-至今， 中国石油大学（华东）， 化学化工学院， 副教授

◎研究方向

[1] 工业催化——烷基化、甲醇转化、催化氧化、电催化等

[2] 石油化工——催化裂解催化剂与工艺研发、气固循环流态化等

◎科研项目

[1] 2022-2025  国家自然科学基金面上项目  甲苯甲醇烷基化与甲醇自转化反应耦合机制及增产烯烃调控措施  主持

[2] 2018-2020  国家自然科学基金青年基金  高硅ZSM-5分子筛烷基化活性位识别及其催化性能调控  主持

[3] 2018-2019  山东省重点研发计划  催化裂化提升管反应器预提升段结构形式优化研究  主持

[4] 2017-2019  山东省自然科学基金  基于高硅ZSM-5分子筛的烷基化催化剂设计及其性能优化  主持

[5] 2014-2016  中国博士后科学基金面上资助  纳米颗粒包覆改善C类粘性颗粒流动性的方法及机制  主持

[6] 2017-2019  校自主创新科研计划  高硅ZSM-5分子筛用于甲苯甲醇烷基化的优化设计及基础研究  主持

[7] 2017-2020  校人才引进项目  高效甲苯甲基化催化剂设计及其稳定性强化方法  主持

[8] 2021-2022  中石油科技项目  非贵金属环保型流化床丙烷催化脱氢制丙烯成套技术工业应用试验  参与

[9] 2021-2023  中石油科技项目  石蜡基原油催化裂解制低碳烯烃催化剂中试工艺条件优化研究  参与

[10] 2020-2021  中石油科技项目  原油催化裂解制烯烃工艺技术中试研究  参与

[11] 2019-2020  中石油科技项目  催化裂化-循环油加氢回炼技术研究  参与

[12] 2019-2021  中石油科技项目  富芳组分催化加氢与催化裂化耦合调控研究  参与

[13] 2018-2019  中石油科技项目  催化柴油窄馏分选择性加氢回炼技术研究  参与

[14] 2018-2020  校自主创新科研计划  新型锡基丙烷脱氢催化剂的优化设计及基础研究  参与

◎代表性论文及专利

近年来，公开发表学术论文50 余篇，其中SCI收录 40 余篇。

[1] Zhu XL*, Wang Y, Wang GW, Hou YF, Yu MX, Yang X, Yin FM. Synergistic co-conversion of pentane and methanol to aromatics over bifunctional metal/ZSM-5 zeolite catalysts. Microporous and Mesoporous Materials (SCI二区TOP, IF = 5.455), 2021, 320: 111107.

[2] Cheng M, Wang Y, Wang WH, Wang GW, Zhu XL*, Li CY. Promoting effect of copper oxide on CsX zeolite catalyst for side-chain alkylation of toluene with methanol. Microporous and Mesoporous Materials (SCI二区TOP, IF = 5.455), 2021, 311: 110732.

[3] Wang Y, Yang X, Hou CX, Yin FM, Wang GW, Zhu XL*, Jiang GY, Li CY. Improved catalytic activity and stability of ba substituted SrTiO3 perovskite for oxidative coupling of methane. ChemCatChem  (SCI二区, IF = 5.686), 2021, 13: 4182-4191.

[4] Zhu XL*, Wang H, Wang GW, Hou YF, Zhang JY, Li CY, Yang CH. Aromatization of n-pentane over Zn/ZSM-5 catalysts: effect of Si/Al ratio and reaction pathway. Journal of Porous Materials (SCI三区, IF = 2.496), 2021, 28: 1059-1067.

[5] Wang SS, Cheng M, Zhu XL*, Lin CH, Wang GW, Zhen XP, Tian LY, Li CY. Effect of swirling gas nozzles on gas-solid flow patterns inside a novel multi-regime riser. Powder Technology (SCI二区, IF = 5.134), 2020, 367: 233-242.

[6] Zhu XL*, Yu MX, Cheng M, Wang Y, Li BQ, Zhang HN, Wang GW, Li CY*. Conceptual fluid catalytic cracking process with the additional regenerated catalyst circulation path for gasoline reprocessing and upgrading with minimum loss. Energy & Fuels (SCI二区TOP, IF = 3.021), 2020, 34: 235-244.

[7] Wang GW, Zhang S, Zhu XL*, Li CY*. Dehydrogenation versus hydrogenolysis in the reaction of light alkanes over Ni-based catalysts. Journal of Industrial and Engineering Chemistry (SCI二区, IF = 4.978), 2020, doi: 10.1002/tcr.201900090.

[8] Zhu XL*, Zhang JY, Cheng M, Wang GW, Yu MX, Li CY*. Methanol aromatization over Mg-P-modified [Zn,Al]ZSM-5 zeolites for efficient coproduction of para-xylene and light olefins. Industrial & Engineering Chemistry Research (SCI二区TOP, IF = 3.375), 2019, 58: 19446-19455.

[9] Zhang JY, Zhu XL*, Zhang SH, Cheng M, Yu MX, Wang GW, Li CY*. Selective production of para-xylene and light olefins from methanol over the mesostructured Zn-Mg-P/ZSM-5 catalyst. Catalysis Science & Technology (SCI二区, IF = 5.726), 2019, 9: 316-326.

[10] Liu JW, Wang GW, Zhu XL*, Li CY*, Shan HH. Temperature-programmed studies of isobutene oxidation over alpha-Bi2Mo3O12: Active oxygen species and reaction mechanism. Applied Surface Science (SCI二区, IF = 5.155), 2019, 470: 846-853.

[11] Zhang JY, Zhu XL*, Wang GW, Wang PZ, Meng Z, Li CY*.The origin of the activity and selectivity of silicalite-1 zeolite for toluene methylation to para-xylene. Chemical Engineering Journal (SCI一区TOP, IF = 8.355), 2017, 327: 278-285.

[12] Zhang HN, Zhu XL*, Chen XC, Miao PP, Yang CC, Li CY*. Fluid catalytic cracking of hydrogenated light cycle oil for maximum gasoline production: effect of catalyst composition. Energy & Fuels (SCI二区TOP, IF = 3.021), 2017, 31: 2749-2754.

[13] Zhu XL, Zhang Q*, Huang C, Wang Y, Yang CH, Wei F. Validation of surface coating with nanoparticles to improve the flowability of fine cohesive powders. Particuology (SCI三区, IF = 2.616), 2017, 30: 53-61.

[14] Zhu XL, Tang C, Wang HF, Li BQ, Zhang Q*, Li CY, Yang CH, Wei F. Monolithic-structured ternary hydroxides as freestanding bifunctional electrocatalysts for overall water splitting. Journal of Materials Chemistry A (SCI一区TOP, IF = 10.733), 2016, 4: 7245-7250.

[15] Zhu XL, Zhang Q*, Wang Y, Wei F. Review on the nanoparticle fluidization science and technology. Chinese Journal of Chemical Engineering (SCI三区, IF = 1.911), 2016, 24: 9-22.

[16] Zhu XL, Tang C, Wang HF, Zhang Q*, Yang CH, Wei F. Dual-sized NiFe layered double hydroxides in situ grown on oxygen-decorated self-dispersal nanocarbon as enhanced water oxidation catalysts. Journal of Materials Chemistry A (SCI一区TOP, IF = 10.733), 2015, 3: 24540-24546.

[17] Zhu XL, Geng Q, Wang GW, Li CY*, Yang CH. Hydrodynamics and catalytic reaction inside a novel multi-regime riser. Chemical Engineering Journal (SCI一区TOP, IF = 8.355), 2014, 246: 150-159.

[18] Zhu XL, Li CY*, Yang  CH, Wang GW, Geng Q, Li T. Gas-solids flow structure and prediction of solids concentration distribution inside a novel multi-regime riser. Chemical Engineering Journal (SCI一区TOP, IF = 8.355), 2013, 232: 290-301.

[19] Zhu XL, Yang CH, Li CY*, Liu YB, Wang L, Li T, Geng Q. Comparative study of gas-solids flow patterns inside novel multi-regime riser and conventional riser. Chemical Engineering Journal (SCI一区TOP, IF = 8.355), 2013, 215: 188-201.

[20] Zhu XL, Jiang S, Li CY*, Chen XB, Yang CH. Residue catalytic cracking process for maximum ethylene and propylene production. Industrial & Engineering Chemistry Research (SCI二区TOP, IF = 3.375), 2013, 52: 14366-14375.

[21] Zhu XL, Wang GW, Geng Q, Li CY*, Yang CH. Pressure drop and apparent solids concentration inside a novel multi-regime riser. Advanced Materials Research (EI收录), 2013, 709: 309-312.

[22] Wang GW*, Jiang YX, Zhang S, Zhu XL, Shan HH. Insight into the Active Co Phase of Co/Al2O3 Catalyst for Ethane Dehydrogenation. Catalysis Letters (SCI三区, IF = 3.186), 2022, 10.1007/s10562-021-03883-3.

[23] Miao PP, Zhu XL, Zhou Z, Feng XP, Miao J, Hou CX, Li CY*. Combined dealkylation and transalkylation reaction in FCC condition for efficient conversion of light fraction light cycle oil into value-added products. Fuel (SCI一区, IF = 6.609), 2021, 304: 121356.

[24] Miao PP, Zhu XL, Guo YL, Miao J, Yu MY, Li CY*. Combined mild hydrocracking and fluid catalytic cracking process for efficient conversion of light cycle oil into high-quality gasoline. Fuel (SCI一区, IF = 6.609), 2021, 292: 120364.

[25] Miao PP, Miao J, Guo YL, Lin CH, Zhu XL, Li CY*. Efficient conversion of light cycle oil into gasoline with a combined hydrogenation and catalytic cracking process: effect of pre-distillation. Energy & Fuels (SCI三区, IF = 3.605), 2020, 34: 12505-12516.

[26] Wang GW, Zhu XL, Li CY*. Recent progress in commercial and novel catalysts for catalytic dehydrogenation of light alkanes. Chemical Record (SCI二区, IF =5.387), 2019, doi: 10.1002/tcr.201900090.

[27] Geng Q, Zhu XL, Yang J, You XH, Liu YB, Li CY*. Flow regime identification in a novel circulating-turbulent fluidized bed. Chemical Engineering Journal (SCI一区TOP, IF = 5.310), 2014, 244: 493-504.

[28] Wang GW, Zhu XL, Zhang JY, Sun YN, Li CY*, Shan HH. Catalytic dehydrogenation of isobutane over Co-based catalysts. RSC Advances (SCI三区, IF = 3.289), 2014, 4: 57071-57082.

[29] Geng Q, Zhu XL, Liu YX, Liu YB, Li CY*, You XH. Gas-solid flow behavior and contact efficiency in a circulating-turbulent fluidized bed. Powder Technology (SCI二区, IF = 2.759), 2013, 245: 134-145.

[30] Shi JL, Wang HF, Zhu XL, Chen CM, Huang X, Zhang XD, Li BQ, Tang C, Zhang Q*. The nanostructure preservation of 3D porous graphene: New insights into the graphitization and surface chemistry of non-stacked double-layer templated graphene after high-temperature treatment. Carbon (SCI一区TOP, IF = 6.198), 2016, 103: 36-44.

[31] Wang HF, Tang C, Zhu XL, Zhang Q*. A 'point-line-point' hybrid electrocatalyst for bi-functional catalysis of oxygen evolution and reduction reactions. Journal of Materials Chemistry A (SCI一区TOP, IF = 8.262), 2016, 4: 3379-3385.

[32] Wang GW, Gao CC, Zhu XL, Sun YN, Li CY*, Shan HH. Isobutane dehydrogenation over metal (Fe, Co, and Ni) oxide and sulfide catalysts: reactivity and reaction mechanism. ChemCatChem (SCI二区, IF = 4.724), 2014, 6: 2305-2314.

[33] Wang GW, Wu WL, Zhu XL, Sun YN, Li CY*, Shan HH. Effect of calcination temperature on isobutane dehydrogenation over Mo/MgAl2O4 catalysts. Catalysis Communications (SCI三区, IF = 3.389), 2014, 56: 119-122.

[34] Tang C, Wang HF, Zhu XL, Li BQ, Zhang Q*. Advances in hybrid electrocatalysts for oxygen evolution reactions: Rational integration of NiFe layered double hydroxides and nanocarbon. Particle & Particle Systems Characterization (SCI二区, IF = 4.367), 2016, 33: 473-486.

[35] Geng Q, Wang P, Zhu XL, You XH, Li CY*. Flow dynamics and contact efficiency in a novel fast-turbulent fluidized bed with ring-feeder internals. Particuology (SCI三区, IF = 2.280), 2015, 21: 203-211.

[36] Wang GW, Zhang HL, Zhu QQ, Zhu XL, Li XY, Wang H, Li CY*, Shan HH.Sn-containing hexagonal mesoporous silica (HMS) for catalytic dehydrogenation of propane: An efficient strategy to enhance stability. Journal of Catalysis (SCI一区TOP, IF = 7.723), 2017, 351, 90-94.

[37] Zhu QQ, Wang GW*, Zhang HL, Zhu XL, Li CY*. n-Butane dehydrogenation over Ni-Sn/SiO₂: Adsorption modes and reaction paths of n-butane and 1-butene. Applied Catalysis A: General (SCI二区TOP, IF = 4.630), 566: 113-120.

[38] Zhu QQ, Zhang HL, Zhang S, Wang GW*, Zhu XL, Li CY*. Dehydrogenation of isobutane over a Ni-P/SiO₂ catalyst: Effect of P addition. Industrial & Engineering Chemistry Research (SCI二区TOP, IF = 3.375), 58: 7934-7943.

[39] Miao PP, Li K, Fan JT, Xu NW, Zhu XL, Li CY*. Efficient ring-opening reaction of tetralin over nanosized ZSM-5 zeolite: Effect of SiO₂/Al₂O₃ ratio and reaction condition. Energy & Fuels (SCI二区TOP, IF = 3.021), 2019, 33: 9480-9490.

[40] Li BQ, Tang C, Wang HF, Zhu XL, Zhang Q*. An aqueous preoxidation method for monolithic perovskite electrocatalysts with enhanced water oxidation performance. Science Advances (SCI一区TOP, IF = 12.804), 2016, 2: e1600495.

[41] Wang GW, Sun NN, Gao CC, Zhu XL, Sun YN, Li CY*, Shan HH. Promoting mechanism of sulfur addition in catalytic dehydrogenation of isobutane over Mo/MgAl2O4 catalysts. Applied Catalysis A: General (SCI二区, IF = 4.012), 2014, 478: 71-80.

◎代表性著作

◎获奖情况及荣誉称号

[1] 2018.11    荣获“青岛西海岸新区高层次人才”紧缺人才

[2] 2015.10    荣获“山东省优秀博士学位论文”

[3] 2013.12    荣获中国石油大学“学术十杰”

◎执教课程

本科生：《化工过程分析与合成》、《石油加工概论》、《专业实验》

◎招收及指导研究生情况

1. 指导研究生情况

协助指导博士研究生1名，独立指导学术研究生2名，专业硕士研究生4名。

已毕业研究生2名，分别前往浙江大学攻读博士、中石化镇海炼化工作。

2. 招生专业及要求

招收化学工程与技术学硕、材料与化工专硕，欢迎化工、应化、能化、化学相关专业同学报考。

◎学术兼职

Applied Catalysis B: Environmental (SCI一区, IF = 19.503)、Chemical Engineering Journal (SCI一区, IF = 13.273)、Journal of Energy Chemistry (SCI一区, IF = 9.676)、ACS Applied Materials & Interfaces (SCI一区、9.229)、Fuel (SCI一区, IF = 6.609)、Applied Catalysis A: General (SCI二区, IF = 5.706)、Microporous and Mesoporous Materials (SCI二区、IF = 5.455)、Powder Technology (SCI二区、IF = 5.134)、Particuology (SCI二区、IF = 3.067)、Industrial & Engineering Chemistry Research (SCI三区, IF = 3.720)、Energy & Fuels (SCI三区, IF = 3.605)等国际期刊审稿人。