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姓名:赵玲
职称:研究员
职务:化工学院副院长、联合化学反应工程研究所所长
所属单位:华东理工大学
电话:021-64253175
传真:021-64253528
电子邮件:zhaoling@ecust.edu.cn

教育背景:
1995/09-1999/07,华东理工大学,化工学院,化学工程专业在职博士;
1990/09-1993/07,华东理工大学,化工学院,化学工程专业硕士;;
1986/09-1990/07,华东化工学院,化学工程系,化学工程专业本科

工作经历:
2004/10 - 现在,华东理工大学,化工学院,研究员;
2007/06,法国Polytech’Lille, USTL,访问教授;
2004/07 - 2004/08,英国University of Birmingham,化工系,访问学者;
2001/11 - 2003/02,英国University of Birmingham,化工系,博士后;
1999/10 - 2004/08,华东理工大学,化工学院,副研究员;
1995/10 - 1999/09,华东理工大学,化工学院,讲师;
1993/07 - 1995/09,华东理工大学,化工学院,助教

研究方向:
多相反应与传递,流场结构调控,超临界流体,聚合物发泡

学术要点:
1.多相反应工程
工程反应动力学:经规划的实验和计算,进行高粘缩聚、液相氧化和烷基化等若干反应过程中的关键机制和主导尺度辨识,在充分认识并利用关键机制和主导尺度及其特征基础上,建立简单可靠的反应动力学模型满足工程应用要求。
反应器流场结构调控:通过实验和CFD研究流体流动与相间接触结构化的手段、效应及优化方法,按目标反应过程的需求构建相应的流动和界面结构,特别是采用特殊结构的内构件,通过不同内构件组合及其操作方式、特定内构件与其相应的操作参数协调等规范和优化反应器的区域与整体流动行为以及相间相互作用,发挥协同增效作用,一方面形成所需流动模型,促进混合;另一方面,改善相态分布,增加相际接触面积和传递系数,强化传质、传热。
2、超临界流体协助的聚合物加工
研究超临界CO2在聚合物中的溶解和扩散行为,认识超临界流体环境中多相体系的传递现象;研究超临界CO2与聚合物的相互作用机制及其调控手段,确定溶入超临界CO2后聚合物结构和性质的动态变化及其表征方法;研究超临界流体对缩聚反应和聚合物改性反应的强化效应;制备适合超临界流体发泡的高熔体强度聚合物;研究CO2发泡聚合物过程及相关设备;研究优化调控超临界流体协助的聚合物处理过程及其相关产品结构性能的手段和方法。

荣誉和奖励:
2002年英国皇家学会K.C. Wong Fellowship,2004年上海市优秀博士论文,2008年上海市 “曙光学者”, 2008年上海市优秀青年教师,2009年教育部新世纪优秀人才,2013年上海市优秀博士论文指导教师,2014年上海市优秀技术带头人。
作为项目负责人承担了973二级子课题、863项目、国家支撑项目子课题、自然科学基金、上海市科委攻关项目以及包括中石化十条龙重大攻关项目在内的企业项目30多项。发表SCI收录论文70余篇,获授权发明专利11项。曾在The 9th WCCE、SuperGreen2013、SPE China 2013、SuperGreen2011、全国超临界流体技术学术及应用研讨会等国际国内学术会议作主题或邀请报告8次。现任上海市化学化工学会理事、化学工程专业委员会副主任,国内化工期刊《化学反应工程与工艺》和《现代化工》以及国际刊物“Journal of Cellular Plastic” 等编委。曾参与获得2011年度国家科技进步二等奖以及省部级科技进步一等奖3次、二等奖1次和三等奖2次,并获得2009年度上海市教学成果一等奖。

2009年至今主要期刊论文:
[1]Dongdong Hu; Jie Chen; Shaojun Sun; Tao Liu*; Ling Zhao. Solubility and Diffusivity of CO2 in IsotacticPolypropylene/Nanomontmorillonite Composites in Melt and Solid States. Ind. Eng. Chem. Res., 2014, 53(7),2673-2683.
[2]Zhenhao Xi, Fanglin Zhang, Hua Zhong, Tao Liu, Ling Zhao*, Lih-Sheng Turng. Microcellular injection molding of in situ modified poly(ethylene terephthalate) with supercritical nitrogen. Poly. Eng. Sci, 2014, DOI: 10.1002/pen.23824
[3]Weizhen Sun, Yi Shi, Jie Chen, Zhenhao Xi, and Ling Zhao*. Alkylation Kinetics of Isobutane by C4 Olefins Using Sulfuric Acid as Catalyst. Ind. Eng. Chem. Res., 2013,52, 15262-25269.
[4]Chen Jie, Liu Tao, Zhao Ling*, Yuan Wei-kang. Experimental Measurements and Modeling of Solubility and Diffusivity of CO2 in Polypropylene/Micro- and Nanocalcium Carbonate Composites. Ind. Eng. Chem. Res., 2013, 52(14), 5100-5110.
[5]Zhong Hua; Xi Zhenhao; Liu Tao; Xu Zhimei; Zhao Ling*. Integrated process of supercritical CO2-assisted melt polycondensation modification and foaming of poly(ethylene terephthalate) . J. Supercrit. Fluid., 2013, 74, 70-79.
[6]Chen Like, Xi Zhenhao,Qin Zhen, Zhao Ling*, Yuan Weikang. Simulation of Continuous Esterification Process of Polyester Polyols. Chinese J Chem. Eng., 2013, 21(3), 246-252.
[7]J. Chen, T. Liu, L. Zhao*, W.K. Yuan. Solubility and Diffusivity of CO2 in Polypropylene/Micro-Calcium Carbonate Composites, J. Supercrit. Fluid., 2013, 77, 33-43.
[8]D.Ch. Li, T. Liu*, Ling Zhao*, W.K. Yuan. Controlling Sandwich-Structure of PET Microcellular Foams Using Coupling of CO2 Diffusion and Induced Crystallization. AIChE J., 2012, 58, 2512-2523.
[9]Jin-Biao Bao, Tao Liu, Ling Zhao Guo-Hua Hu, Xiaran Miao, Xiuhong Li. Oriented foaming of polystyrene with supercritical carbon dioxide for toughening, Polymer, 2012, 53, 5983-5993.
[10]Yang Xu, Tao Liu, Lei Li, Da-chao Li, Wei-kang Yuan, Ling Zhao. Controlling crystal phase transition from Form II to I in isotactic poly-1-butene using CO2, Polymer, 2012, 53 , 6102-6111.
[11]J. Chen, T. Liu, L. Zhao*, W.K. Yuan. Determination of CO2 solubility in isotactic polypropylene melts with different polydispersities using magnetic suspension balance combined with swelling correction. Thermochim. Acta, 2012,530, 79– 86.
[12]Sun, Weizhen; An, Meiying; Zhong, Weimin; Zhao, Ling*, Kinetics of COx Formation in the Homogeneous Metal/Bromide Catalyzed Aerobic Oxidation of p-Xylene. Int. J. Chem. Kine t., 2012, 277-283.
[13]J.B. Bao, T. Liu, L. Zhao*, D. Barth, G.H. Hu*. Supercritical carbon dioxide induced foaming of highly oriented isotactic polypropylene. Ind. Eng. Chem. Res., 2011, 50 (23), 13387–13395.
[14]L. Li, T. Liu, L*. Zhao*. Direct Fabrication of Porous Isotactic Poly-1-Butene with Form I From the Melt Using CO2. Macromol. Rapid Commun., 2011, 32, 1834-1838.
[15]L. Li, T. Liu*, L. Zhao*, W. K. Yuan. Effect of compressed CO2 on the melting behavior and βα-recrystallization of β-form in isotactic polypropylene. J. Supercrit. Fluid, 2011, 60, 137-143.
[16]D.Ch. Li, T. Liuv, Ling Zhao*, W.K. Yuan. Foaming of linear isotactic polypropylene base on its non-isothermal crystallization behaviors under compressed CO2. J. Supercrit. Fluid., 2011, 60, 89-97.
[17]L. Li, T. Liuv, L. Zhaov. Direct melt-crystallization of isotactic poly-1-butene with form I′ using high-pressure CO2. Polymer, 2011, 52, 5659-5668.
[18]G.Sh. Tong, T. Liu, Sh.M. Zhu, B.Sh. Zhu, D.Y. Yan, X.Y. Zhu*, L. Zhao*. Facile fabrication and application of Au@MSN nanocomposites with a supramolecular star-copolymer template. J. Mater. Chem., 2011, 21, 12369-12374.
[19]L. Li, T. Liu*, L. Zhao*, W. K. Yuan. CO2-induced polymorphous phase transition of isotactic poly-1-butene with form III upon annealing. Polymer, 2011, 52, 3488-3495.
[20]L. Li, T. Liu*, L. Zhao*, W. K. Yuan. CO2-Induced Phase Transition of Isotactic Poly-1-butene with Form III upon Heating. Macromolecules, 2011, 44, 4836-4844.
[21]J.B. Bao, T. Liu, L. Zhao*, G.H. Hu*. Carbon Dioxide Induced Crystallization for Toughening Polypropylene. Ind. Eng. Chem. Res., 2011, 50, 9632-9641.
[22]D.Ch. Li, T. Liu*, L. Zhao*, X.S. Lian and W.K. Yuan. Foaming of Poly(lactic acid) Based on Its Non-Isothermal Crystallization Behavior under Compressed Carbon Dioxide, Ind. Eng. Chem. Res., 2011,50, 1997-2007.
[23]J.B. Bao, T. Liu, L. Zhao*, G.H. Hu*. A two-step depressurization batch process for the formation of bi-modal cell structure polystyrene foams using scCO2. J. Supercrit. Fluid., 2011, 55, 1104-1114.
[24]Weizhen Sun, Ling Zhao*. Simulation of Secondary Oxidation of p-Xylene in Liquid Phase. Ind. Eng. Chem. Res. 2011, 50, 2548–2553.
[25]T. Liu, D.ch. Li, L. Zhao *and W.K. Yuan .Manipulation of polymer foam structure based on CO2-induced changes in polymer fundamental properties, Particuology, 2010, 8(6), 607–612;
[26]Dachao Li, Liu Tao*, Ling zhao* and Yuan W. K., Solubility and diffusivity of carbon dioxide in solid state isotactic polypropolene by the pressure-decay method. Ind. Eng. Chem. Res., 2009, 48(15), 7117-7124.
[27]Tong G. S., Liu T. *, Zhao L*,Hu.L.X. and Yuan W. K., Supercritical carbon dioxide assisted preparation of polypropylene grafted acrylic acid with high grafted content and small gel percent. J. Supercritical Fluids, 2009, 48(3), 261-268.
[28]Lei Li, Tao Liu, Ling Zhao* and Wei-kang Yuan CO2-Induced Crystal Phase Transition from Form II to I in Isotactic Poly-1-butene, Macromolecules, 2009, 42 (6), 2286–2290.
[29]Xiu-Lei Jiang, Tao Liu, Zhi-Mei Xu, Ling Zhao*, Guo-Hua Hu*, Wei-Kang Yuan, Effects of crystal structure on the foaming of isotactiic polypropylene using supercritical carbon dioxide as a foaming agent. J. Supercritical Fluids, 2009, 48(2), 267-175.
[30]Li Jun*, Zhao Ling, Lu Guanzhong, Activation of methane over perovskite catalysts ,Ind. Eng. Chem. Res., 2009, 48(2), 641-646.

 



   
     
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