New Concepts in Lewis Acidity, Catalysis, and Polymer Science: Functional Main Group Cages

路易斯酸、催化和高分子科学的新概念：功能主族笼

• 批准号: RGPIN-2018-05574
• 负责人: Chitnis, Saurabh
• 金额: $ 2.48万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=685314
• 关键词: New; Concepts; Lewis; Acidity; Catalysis

The elements of the periodic table combine with one another to give molecules which are the building blocks of our material world. Defining the shape, size, and properties of these blocks is an essential first step towards creating new useful materials such as plastics, catalysts, and fuels. Chemists have traditionally focused on the organic elements (C, N, H, O) as a source of useful molecules, in part due to the historic reliance upon organic element-rich feedstocks (e.g. petroleum and natural gas). The remaining 77 or so stable elements of the periodic table have received less attention by comparison, despite the fact that many of them are very abundant on earth (e.g. silicon). ******With the aid of this Discovery Grant, the Chitnis group will begin operations at Dalhousie University in July 2018 and establish a program of extracting exciting functional properties from the abundant and often benign elements of the p-block of the periodic table. One targeted property will be selective binding and modification of small molecules that are found in industrial emissions or in natural or anthropogenic toxins. To achieve this, the group will make liquids that contain dissolved inorganic cages, making them porous (like a sponge), and then enhance the binding abilities (Lewis acidity) of the cages. Depending on the size of the cages in the liquid, these porous liquids will bind different molecules. We will also discover new catalysts for safer and more efficient manufacturing of commodity chemicals and pharmaceuticals. For this purpose, we will focus on the chemistry of bismuth cages as this element is inexpensive and nontoxic. Lastly we will link together inorganic cage molecules into polymers that could one day be incorporated into electronic devices as smart responsive materials. In particular we will target charged polymers which will exhibit good water solubility and conductivity, making them potentially useful in both biological and electronic applications. In summary our research will exert control over the shape, size and electronic properties of inorganic cages to devise useful chemical systems for incorporation into technologies of daily relevance.******This research program will also train undergraduate and graduate students to be chemists who can independently conceive, execute, and communicate scientific projects, using state-of-the-art equipment. The skills developed through this training are essential components of a broad range of careers in government, industry or academia. The creation of a scientifically-literate workforce is essential for sustaining the pace of innovation needed for Canada to remain a technologically advanced nation.

元素周期表中的元素相互联合收割机形成分子，这些分子是我们物质世界的基石。确定这些块体的形状、大小和性质是创造新的有用材料（如塑料、催化剂和燃料）的重要第一步。化学家传统上关注有机元素（C，N，H，O）作为有用分子的来源，部分原因是历史上对富含有机元素的原料（例如石油和天然气）的依赖。相比之下，元素周期表中剩下的77种左右稳定元素受到的关注较少，尽管其中许多元素在地球上非常丰富（例如硅）。** 在这项发现补助金的帮助下，Chitnis小组将于2018年7月在达尔豪西大学开始运作，并建立一个从周期表p区丰富且通常是良性的元素中提取令人兴奋的功能特性的计划。一个目标特性将是选择性结合和修饰工业排放物或天然或人为毒素中发现的小分子。为了实现这一目标，该小组将使液体含有溶解的无机笼，使它们多孔（像海绵），然后提高结合能力（刘易斯酸性）的笼。根据液体中笼的大小，这些多孔液体将结合不同的分子。我们还将发现新的催化剂，以更安全、更有效地生产日用化学品和药品。出于这个目的，我们将专注于铋笼的化学，因为这种元素是廉价和无毒的。最后，我们将把无机笼分子连接成聚合物，有朝一日可以作为智能响应材料纳入电子设备。特别是，我们将针对带电聚合物，这些聚合物将表现出良好的水溶性和导电性，使它们在生物和电子应用中具有潜在的用途。总之，我们的研究将控制无机笼的形状，大小和电子特性，以设计有用的化学系统，用于纳入日常相关技术。该研究计划还将培养本科生和研究生成为化学家，他们可以独立构思，执行和交流科学项目，使用最先进的设备。通过这种培训开发的技能是在政府，工业或学术界广泛的职业生涯的重要组成部分。创造一支具有科学素养的劳动力队伍对于保持加拿大保持技术先进国家所需的创新步伐至关重要。