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化学和生物催化中的选择性 (SeleCa)","IRTG 1628 Selectivity in Chemo- and Biocatalysis (SeleCa)","Faculty of Mathematics and Natural Sciences","irtg-1628-selectivity-in-98362","全球快速变化的条件和即将到来的原材料基础转变，使得选择性转化所需的催化剂需要得到根本性的改进，以确保化学中间体和产品的可持续生产。国际研究生院“化学和生物催化中的选择性 (SeleCa)”的目标是实现对高效和选择性均相催化过程的理解和开发。通过跨学科方法，结合高效化学催化剂、生物催化剂和集成方法的各个方面，以选择性地转化高度功能化的分子。研究用于C-H键活化、C-C和C-X键形成的非对称催化以及选择性聚合的新型催化剂，构成化学催化重点。选择性全细胞生物催化剂、用于天然产物合成的酶和创新的糖缀合物合成构成生物催化重点。混合催化剂、超分子蛋白质替代物以及化学-酶法聚合反应相结合的新型综合概念，构成了化学和生物催化之间的连接桥梁。亚琛工业大学的九个研究小组和于利希研究中心的一个附属研究小组将与大阪大学的九个研究小组在化学和生物催化领域进行合作。在一个为选定研究生设计的培训项目中，将结合跨学科研究方向，开发新的化学和生物催化转化方法，并培养面向化学的研究生在生物催化方面的能力，以及面向生物学/生物技术的研究生在化学催化方面的能力。来自两种文化和社会背景差异很大的机构的研究生之间的跨国交流，建立在多年科学和个人合作的坚实基础之上。在与不同文化圈打交道时确保安全，是未来科学人才在全球化世界中一项重要的资格特征。","401","化学",{"id":114,"name":115,"program":116,"department":117,"degree":55,"code":118,"gpa":10,"materials":10,"gre":10,"gmat":10,"ielts":10,"toefl":10,"studyMode":13,"years":10,"unit":36,"tuition":10,"startDate":10,"deadlineDate":10,"description":119,"add01Html":10,"universityId":4,"subjectAreaCode":57,"subjectAreaName":59,"subjectCode":79,"subjectName":80,"qsRank":11,"usNewsRank":11,"timesRank":11,"shanghaiRank":11,"dstatus":10,"createdTime":10,"updatedTime":10,"universityName":6,"unEnglishName":7,"unAbbreviation":8,"unQsRank":41,"unCode":9,"unCity":10,"universityCode":10,"countryCode":10},98363,"GRK 1632 实验与构造代数","GRK 1632 Experimental and Constructive Algebra","Teaching and Research Area Mathematics (Algebra)","grk-1632-experimental-constructive-98363","实验与构造代数研究生院（GRK 1632）利用实验方法研究抽象代数问题。计算机在此过程中充当显微镜和工具。相应方法的不断发展一方面能够深入了解数学世界，另一方面也允许用户在无需深入研究通常困难的底层理论的情况下应用算法和结果。研究重点是群论，这是普遍存在的对称概念的数学抽象。计算机是数学家的显微镜，他们用它来实验性地研究抽象给定的对象。相应方法的不断发展一方面能够深入了解数学世界，另一方面也允许用户在无需深入研究通常困难的底层理论的情况下应用算法和结果。这种实验方法也为年轻博士生理解深奥的数学事实开辟了一条直接途径。该研究生院的第二个特点是“内数学桥梁建设”。参与的科学家在数学的不同领域进行研究，这些领域之间存在着多样化的联系，本研究生院旨在在不同方向上进一步扩展和加强这些联系。由此产生的协同效应通常会带来创新的方法和替代视角，最终不仅会显著改进算法方法。除了构造性方法外，对称性也是一个贯穿始终的共同原则。每篇博士论文都位于至少两位参与教授研究领域的交叉点，从而提供了对方法学和主题不同的工作领域的见解，从而以很少的额外工作量拓宽了博士生的科学教育。",24,1772699294757]