UNS: Collaborative Research: Effects of Nano-Bio Interactions on Nanoparticle Fate and Transport in Porous Media

UNS：合作研究：纳米生物相互作用对多孔介质中纳米颗粒命运和传输的影响

• 批准号: 1705346
• 负责人: Kurt Pennell
• 金额: $ 26.15万
• 依托单位: Brown University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-09-01 至 2021-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1705346&HistoricalAwards=false
• 关键词: UNS; Collaborative; Research; Effects; Nano

Despite dramatic increases in the production and use of engineered nanomaterials in industrial and consumer products, very little is known about the fate and transport of nanoparticles following their release into the environment. The overall goal of this project is to better understand the interactions between engineered nanoparticles and microbial communities, and to use this information to improve predictions of nanoparticle accumulation and mobility in soils, groundwater, and water treatment systems. To broaden the educational outreach and practical implications of this work, the project includes research experiences for undergraduate students and the development of interactive, multi-media instructional tools that will be incorporated into educational and training programs run by the Center for Engineering Education and Outreach and Center for Science, Technology, Engineering and Math Diversity. Research conducted over the past ten years has greatly improved our knowledge of nanoparticle aggregation and mobility over a range of environmentally-relevant conditions, and has informed the development of mathematical models capable of describing nanoparticle transport and retention in membranes, filter beds and aquifer materials. At the same time, numerous studies have explored the impacts of nanoparticles on cellular systems, aquatic invertebrates, fish, and microorganisms. The overall goal of this research project is to combine these two lines of research to investigate the role of nano-bio interactions on nanoparticle fate and transport in porous media. The research project is coupling nanoparticle characterization and biotic experiments with dynamic transport studies to quantify the effects of nano-bio interactions on the mobility and fate of representative engineered nanomaterials (iron oxide and magnesium oxide) in aquifer materials and natural soils. Research activities are being structured around three tasks, (1) determination of nanoparticle deposition and release as a function of surface coating aging, biopolymers, and solution composition using a quartz crystal microbalance, (2) assessment of the effects of biopolymers on nanomaterial mobility and retention in abiotic columns, and (3) measurement of nanoparticle transport, deposition, and aging in aerobic and anaerobic bio-active soil columns. Novel aspects of the research include the direct coupling of microbial-particle interactions with transport, assessment of bio-related deposition, direct observation of nanoparticle behavior using flow-through scanning electron microscopy and cryo-transmission electron microscopy techniques. Results obtained from this work are being used to explore the role of microbial communities in the aging nanoparticle surface coatings, and the impacts of filter ripening and site blocking on nanoparticle attachment processes and mobility in the environment. To extend the impact of this work beyond traditional academic boundaries, research outcomes are being incorporated into model-based tutorials, short instructional videos, and illustrative case studies and modeling tools that will be disseminated through collaborations and participation in initiatives with the Center for Science Technology, Engineering and Math Diversity, the Bridge to Engineering Success at Tufts, and the Center for Engineering Education and Outreach at Brown.

尽管工程纳米材料在工业和消费品中的生产和使用急剧增加，但人们对纳米颗粒释放到环境中后的命运和运输知之甚少。该项目的总体目标是更好地了解工程纳米颗粒和微生物群落之间的相互作用，并利用这些信息来改善对土壤，地下水和水处理系统中纳米颗粒积累和流动性的预测。为了扩大这项工作的教育推广和实际影响，该项目包括本科生的研究经验和互动，多媒体教学工具的开发，将被纳入由工程教育和推广中心和科学中心运行的教育和培训计划，技术，工程和数学多样性。在过去十年中进行的研究极大地提高了我们对纳米颗粒聚集和流动性在一系列环境相关条件下的知识，并为能够描述纳米颗粒在膜，滤床和含水层材料中的运输和保留的数学模型的开发提供了信息。与此同时，许多研究探讨了纳米颗粒对细胞系统、水生无脊椎动物、鱼类和微生物的影响。本研究计划的总体目标是将这两条研究线联合收割机结合起来，研究纳米生物相互作用对纳米颗粒在多孔介质中的命运和运输的作用。该研究项目将纳米颗粒表征和生物实验与动态迁移研究相结合，以量化纳米生物相互作用对含水层材料和自然土壤中代表性工程纳米材料（氧化铁和氧化镁）的流动性和归宿的影响。研究活动围绕三个任务进行，（1）使用石英晶体微量天平确定纳米颗粒沉积和释放作为表面涂层老化，生物聚合物和溶液组成的函数，（2）评估生物聚合物对非生物柱中纳米材料流动性和保留的影响，以及（3）测量纳米颗粒的运输，沉积，以及在有氧和厌氧生物活性土柱中老化。研究的新方面包括微生物-颗粒相互作用与运输的直接耦合，生物相关沉积的评估，使用流通扫描电子显微镜和低温透射电子显微镜技术直接观察纳米颗粒行为。从这项工作中获得的结果正在被用来探索老化的纳米粒子表面涂层中的微生物群落的作用，以及过滤器成熟和网站阻塞对纳米粒子附着过程和环境中的流动性的影响。为了将这项工作的影响力扩展到传统的学术界限之外，研究成果正在被纳入基于模型的教程，简短的教学视频，以及说明性的案例研究和建模工具，这些工具将通过与科学技术中心的合作和参与来传播，工程和数学多样性，塔夫茨工程成功的桥梁，以及布朗大学工程教育和推广中心。

项目成果

Effects of Rhamnolipid Biosurfactant on the Dissolution and Transport of Silver Nanoparticles in Porous Media

• DOI: 10.1039/d1en00185j
• 发表时间: 2021-07
• 期刊: Environmental Science: Nano
• 作者: Shuchi Liao;Chen Liu;Dorothea Pinchbeck;Natalie L. Cápiro;J. Fortner;L. Abriola;K. Pennell