为提升我校研究生课程体系国际化程度,加快我校研究生教育国际化进程,增强研究生创新意识与创新能力,培养具有国际视野的高质量人才,由郑州大学研究生院主办、化学与分子工程学院承办的2017年研究生国际暑期学校——化学分校于2017年8月13日至16日在郑州大学新校区化学馆化学与分子工程学院学术报告厅(208室)举行。通过聘请国内外知名学者讲授(全英授课)学术前沿课程和专业基础课程,实现优质教学资源共享,为研究生搭建夯实专业基础、提高研究水平、培养创新能力的国际交流平台。
一、招生对象及要求
国内外学校相关专业在校研究生、本院研究生及本校相关专业在校研究生;准备第一志愿报考我院硕士研究生的全日制本科三年级在校生(化学专业学生,其中一本高校的学生专业排名在年级前20%,二本高校的学生专业排名在年级前10%。);因全程采用英语授课,要求学员英语功底好,原则上要求本科生英语通过CET4以上,研究生英语通过CET6以上,且具有英语听课的适应能力。
二、招生计划
本次暑期学校,计划招收学生80-100人,其中本科生20-40名,研究生40-60名。
三、教学安排:
1.2017年8月13日学生报到,8月14日上午开学典礼,8月16日结业。
2.邀请加拿大皇家科学院院士、加拿大McGill University, Chao-Jun Li 教授, 日本京都大学副校长Hiroshi KITAGAWA教授,中科院上海有机所丁奎岭 院士 和 北京大学 席振峰 院士为学员授课。授课内容如下(暂定):
Prof. Chao-Jun Li
Title:Green Chemistry towards Future Sustainability
Chemistry plays the central role in modern sciences and technologies. The efficient transformation of matters is vital in any new products in the pharmaceutical, materials science, microelectronics, energy and biotech industries. On the other hand, chemical manufacturing and chemical products have also affected us adversely from personal, local, national, and international scales. As a new philosophy over the last two decades, Green Chemistry through the 12 principles of green chemistry has emerged to develop the next generation of chemical science and technologies, as well as chemical products to meet such challenges in a proactive manner both environmentally and economically, ideally from readily available natural resources directly in a benign solvent with renewable energy. This talk will discuss the fundamental principles of green chemistry and our own laboratory’s exploration of various unconventional chemical reactivity to simplify protection-deprotections, halogenation-dehalogenation as well as the possibility of chemical transformations beyond functionalization and defunctionalization in syntheses, and for solar energy conversions. Many of these new reactions can also be used to functionalize biomass directly.
Prof. Zhenfeng Xi
Title: Chemistry of Organo-di-Metallic Reagents Cooperative Effects and Applications
1)The development of organometallic reagents remains one of the most important frontiers in synthetic chemistry. Commonly used organometallic reagents (such as RLi and RMgBr) are typically monometallic compounds, although they aggregate in many cases. When two carbon–metal bonds are in the same molecule in close proximity, however, these two carbon–metal moieties may exhibit novel reactivity. In this course, new reactions and synthetic applications of the organo-di-metallic reagents, with focus on 1,4-dilithio-1,3-butadienes, will be outlined.
2)The dimetallic 1,4-dilithio-1,3-butadienes and their transmetallated derivatives provide unique synthetic organometallic reagents that are very different from monometallic reagents, both in terms of reactivity and synthetic application. These organo-dimetallic reagents provide access to interesting and useful compounds that are not available by other means. Moreover, given the possibilities afforded, the study of organo-dimetallic and organo-polymetallic compounds should yield further synthetic applications in the near future.
3)Three major topics will be discussed in this course. Part I: Synthesis and Structural Characterization of Organo-di-Metallic Reagents; Part II: Semibullvalene and Diazasemibullvalene: Recent Advances in the Synthesis, Reaction Chemistry, and Synthetic Applications; Part III: Metalla-aromatics and Spiro Metalla-aromatics.
Prof. Hiroshi KITAGAWA
Title:
1. Low-dimensional electron systems situated on dimensional crossover region.
2. Solid-state protonics using MOFs and SurMOFs, and nano-ionics using nanomaterials.
3. Creation of Novel Solid-Solution Alloy Nanoparticles on the Basis of Density-of-States Engineering by Interelement Fusion.
4. Molecular conductors and conducting MOFs.
Prof. Kuiling Ding
Title:Chiral Catalyst Evolution: Rational Design and Serendipity
1) Development of practical methods for asymmetric synthesis of optically active compounds represents a great challenge in the area of chiral chemistry, in which chiral ligand and catalyst design plays a critically important role. As our continuing effort to develop highly efficient chiral catalysts for homogeneous asymmetric reactions, the first part of presentation will focus on the stories of chiral catalyst evolution based on the mechanistic understanding and serendipity.
2) The second part will present a conceptually new strategy, i.e. “self-supporting” approach, for the immobilization of homogeneous catalysts through self-assembly of chiral multi-topic ligands and metal ions, without using any support. In addition to the simple recovery and convenient recycle commonly associated with heterogeneous catalysts, such kind of homochiral metal-organic assemblies may also exhibit advantages of facile preparation, robust chiral structures and excellent enantioselectivities. These remarkable features coupled with the versatile methods for rational design and synthesis of the multitopic chiral ligand, suggest a considerable scope of application of this “self-supporting” strategy in the development of new, efficient, and practical catalysts for the heterogeneous asymmetric catalysis.
3.主讲教授与学员座谈、交流;组织参观学科实验室、我院实验中心仪器共享平台及与学科相关老师进行座谈。
四、报名与录取
1.报名时间:即日起至2017年6月29日止
2.申请报名
(1)下载填写报名申请表
(2)请将填写完整的申请表、学生证和身份证电子版于6月29日前发送到如下电子邮箱:hxyb@zzu.edu.cn
收件人:刘晨湘, 联系电话:0371-67781815
(3)录取
郑州大学化学与分子工程学院将聘请相关领域专家,根据申请人提供的材料对其进行综合评价,并作为主要录取依据。录取结果拟于7月3日前在郑州大学化学与分子工程学院主页上公布。入选学生需在7月5日前确认是否参加,逾期未确认视为放弃此资格。
(4)报到地点:郑州大学化学与分子工程学院研究生办
五、食宿及交通费:我院将为入选学生提供学习期间在校的食宿(学校或家庭所在地是郑州的学生原则上不安排住宿)。外地学生请自行预定往返车票,我院将资助外地学生往返郑州的火车硬座票或汽车票费用,学生须提供往返车票票据。另外为学员提供自习地点(化203教室)和电子阅览室(化205室)进行自习和互联网检索。
六、注意事项:
1.学生报到时需携带身份证、学生证。
2.暑期学校举办期间,要求学生全程遵守暑期学校相关规定。
3.学员须具有健康的身体和良好的心理素质,如发生医疗费用及个人行为导致的意外事故由个人承担。
以上学生经考核合格,顺利结业的学生可获暑期学校结业证书,本校研究生并获得2个学分,冲抵相关选修课学分。对于参加暑期学校的本科生第一志愿报考我校并被录取后,在统招生中优先享受学业全额奖学金(第一学年),并获得一次性奖励5000元。
欢迎广大在读本科生、硕士研究生、博士研究生积极报名参加本次暑期学校!
郑州大学研究生院
郑州大学化学与分子工程学院
2017年6月22日