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Smart Porous 3D Macrostructures of Graphene Oxide for Selective Removal and Transformation of Contaminants from Water

用于选择性去除和转化水中污染物的智能多孔 3D 氧化石墨烯宏观结构

基本信息

批准号：
RGPIN-2020-05436
负责人：
Yousefi, Nariman
金额：
$ 2.04万
依托单位：
Ryerson University
依托单位国家：
加拿大
项目类别：
Discovery Grants Program - Individual
财政年份：
2020
资助国家：
加拿大
起止时间：
2020-01-01 至 2021-12-31
项目状态：
已结题

来源：
https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=717143
关键词：
Smart Porous 3D Macrostructures Graphene

项目摘要

Over 650 million people, including a large number of Canadian Northern and indigenous communities, do not have access to safe and clean water. Canada, among many other countries, has made a commitment to remove barriers against access to safe and clean water by 2030 within the United Nations Sustainable Development Goals framework. As such, point of use (POU) water treatment devices are alternatives for centralized water treatment systems in remote and sparsely populated areas, such as many of the Northern and indigenous communities that lack access to clean water. Although progress has been made in past years, POU devices still lack the required efficiency to replace centralized water treatment facilities. The scope of this research program is to investigate the possibility of using graphene oxide (GO), a novel carbon-based nanomaterial, to develop multifunctional and efficient POU devices. GO is self-assembled into highly porous 3D macrostructures (3DMs) similar to sponges. One major objective of the proposed research program is to understand the critical role of processing parameters on the properties of 3DMs such as specific surface area, mechanical properties and surface chemistry. Another major goal of this research program is to improve the mechanical properties of GO 3DMs so that they can withstand several regeneration and reuse cycles. Various types of cellulose nanocrystals (CNCs) will be used in conjunction with GO nanosheets to self-assemble them into hybrid 3DMs. The resulting mechanically robust 3DMs will be tested under realistic regeneration and reuse scenarios and their long term robustness will be evaluated. For regeneration, simple strategies available in any household such as use of weak acids (vinegar) will be investigated. Lack of contaminant selectivity is a major obstacle for commercial and large scale use of GO-based 3DMs for water treatment. 3DMs will be treated with components that selectively target contaminants of concern including oils and organic compounds such as pharmaceuticals and toxins, waterborne bacteria, heavy metals and micro- and nanoplastics. Apart from selectivity, this research program also aims to transform the removed contaminants into less harmful compounds. The 3DMs will be surface functionalized with chemical agents that convert oils and organic compounds into smaller and less harmful molecules, kill harmful waterborne bacteria, and interact with heavy metal ions to convert them into less harmful organometallic compounds. The results of this research program will help bring equity in access to safe and clean water to Canadian indigenous and Northern communities, as well as any community around the world with limited access to centralized water treatment facilities. The POU devices will also find applications in disaster relief scenarios where access to centralized water treatment facilities becomes restricted.

超过6.5亿人，包括大量加拿大北方和土著社区，无法获得安全和清洁的水。加拿大和其他许多国家一样，承诺在联合国可持续发展目标框架内，到2030年消除获得安全和清洁水的障碍。因此，使用点（POU）水处理装置是偏远和人口稀少地区（例如许多无法获得清洁水的北方和土著社区）的中央水处理系统的替代品。虽然在过去几年中取得了进展，但POU装置仍然缺乏取代集中式水处理设施所需的效率。该研究计划的范围是研究使用氧化石墨烯（GO），一种新型的碳基纳米材料，开发多功能和高效POU设备的可能性。GO自组装成类似于海绵的高度多孔的3D宏观结构（3DM）。拟议的研究计划的一个主要目标是了解工艺参数对3DM性能的关键作用，如比表面积，机械性能和表面化学。该研究计划的另一个主要目标是改善GO 3DM的机械性能，使其能够承受多次再生和重复使用循环。各种类型的纤维素纳米晶体（CNC）将与GO纳米片结合使用，以将它们自组装成混合3DM。由此产生的机械坚固的3DM将在现实的再生和再利用场景下进行测试，并对其长期坚固性进行评估。对于再生，将研究任何家庭可用的简单策略，例如使用弱酸（醋）。污染物选择性的缺乏是基于GO的3DM用于水处理的商业和大规模使用的主要障碍。3DM将使用选择性针对关注污染物的成分进行处理，包括油和有机化合物，如药物和毒素，水生细菌，重金属以及微米和纳米塑料。除了选择性，该研究计划还旨在将去除的污染物转化为危害较小的化合物。3DM将用化学试剂进行表面功能化，将油和有机化合物转化为更小，危害更小的分子，杀死有害的水生细菌，并与重金属离子相互作用，将其转化为危害更小的有机金属化合物。这项研究计划的结果将有助于使加拿大土著和北方社区以及世界上任何社区在获得集中水处理设施方面的机会有限。POU设备还将在灾难救援场景中找到应用，其中集中式水处理设施的访问受到限制。