Organized Nanomaterials for Enhanced Understanding and Performance of Electrochemical Devices

有序纳米材料可增强对电化学装置的理解和性能

• 批准号: RGPIN-2018-04747
• 负责人: Birss, Viola
• 金额: $ 13.7万
• 依托单位: University of Calgary
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=747780
• 关键词: Organized; Nanomaterials; Enhanced; Understanding; Performance

This research is focused on the development of a range of new nanomaterials that have many useful applications, including for clean energy conversion and storage technologies (e.g., fuel cells, electrolysis cells involving CO2 conversion, redox flow batteries, etc), with an important sub-goal being to fabricate these in a highly organized fashion so that their properties can be better exploited and also more easily evaluated. In one main branch of this research program, we will continue to develop an exciting new family of high surface area carbon nanomaterials (nanoporous carbon scaffolds, NCS). These are self-supported, conducting membranes, developed recently in the Birss group, that contain highly ordered and fully interconnected nano-sized pores, with a structure similar to a honeycomb. A key goal of our research will be to determine the optimum NCS pore size and thickness that results in the least difficulty in terms of moving solution and gas-phase reactants quickly and easily through the pores during electrochemical cell operation, while still retaining the very high real surface area required for use as a catalyst in energy conversion/storage applications. Using organic chemistry, the internal surfaces of the NCS materials will be modified to enable the attachment of catalytic nanoparticles to the NCS surface for various applications and to influence several other properties of the NCS, including how well water wets' their surfaces. These modifications will be made to better understand and improve the performance of carbon supports under the conditions encountered within fuel cells, capacitors and batteries, with comparisons to be made with ultra-smooth carbon surfaces as well. Another part of the proposed research complements other research in our group, in which metal nanoparticles, such as platinum or tiny nanoparticles with one metal inside their core and a second metal in a thin shell layer, are being developed for a wide range of catalyst applications. We believe the functional groups on the NCS surface will directly influence the size and distribution of these types of NPs during fabrication. Finally, we will attempt to coat the internal surfaces of the NCS with an ultrathin catalytic oxide film and test this composite nanomaterial for its ability to convert CO2 to useful products in a room temperature, aqueous, electrolysis cell. The conversion/utilization of captured CO2 is a key approach being used to reduce CO2 emissions into the atmosphere. In addition to employing the most advanced instruments and tools available for this research, these projects will serve to train up to 20 students over five years in these areas of critical importance to Canada and the world.

这项研究的重点是开发一系列新的纳米材料，这些材料有许多有用的应用，包括清洁能源转换和存储技术（例如，燃料电池，涉及二氧化碳转换的电解电池，氧化还原液流电池等），一个重要的子目标是以高度有组织的方式制造这些材料，以便更好地利用它们的性能，也更容易评估。在这个研究项目的一个主要分支中，我们将继续开发一个令人兴奋的高表面积碳纳米材料新家族（纳米多孔碳支架，NCS）。这是Birss小组最近开发的自支撑导电膜，包含高度有序且完全相互连接的纳米级孔，结构类似蜂窝。我们研究的一个关键目标是确定最佳的NCS孔径和厚度，从而在电化学电池操作过程中快速、轻松地移动溶液和气相反应物，同时仍然保持在能量转换/存储应用中用作催化剂所需的非常高的实际表面积。利用有机化学，NCS材料的内部表面将被修饰，以使催化纳米颗粒附着在NCS表面，用于各种应用，并影响NCS的其他一些特性，包括水润湿其表面的程度。这些改进将更好地理解和提高碳支撑在燃料电池、电容器和电池中遇到的条件下的性能，并与超光滑碳表面进行比较。这项研究的另一部分补充了我们小组的其他研究，其中金属纳米颗粒，如铂或在其核心内含有一种金属而在薄壳层中含有第二种金属的微小纳米颗粒，正在被开发用于广泛的催化剂应用。我们认为NCS表面的官能团在制造过程中将直接影响这些类型NPs的尺寸和分布。最后，我们将尝试在NCS的内部表面涂上一层超薄的催化氧化膜，并测试这种复合纳米材料在室温、水电解电池中将二氧化碳转化为有用产品的能力。捕获的二氧化碳的转化/利用是减少二氧化碳排放到大气中的关键方法。除了采用最先进的仪器和工具进行这项研究外，这些项目将在五年内在对加拿大和世界至关重要的这些领域培养多达20名学生。