KC Donnelly Externship Admin Supplement for Francisco Leniz P42ES007380 UKSRC

KC Donnelly 弗朗西斯科·莱尼兹 (Francisco Leniz) 实习管理补充 P42ES007380 UKSRC

• 批准号: 10580946
• 负责人: Kelly G Pennell
• 金额: $ 1.45万
• 依托单位: UNIVERSITY OF KENTUCKY
• 依托单位国家: 美国
• 财政年份: 1997
• 资助国家: 美国
• 起止时间: 1997-04-07 至 2023-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10580946
• 关键词: Anions; Arsenic; Case Study; Characteristics; Communities; Development; Excision; Goals; Ions; Knowledge; Lanthanoid Series Elements; Lead; Learning; Manuscripts; Membrane; Persons; Poly-fluoroalkyl substances; Polymers; Population; Process; Property; Recording of previous events; Research; Research Project Grants; Selenium; Societies; Technology; Testing; Universities; Water; Water Pollutants; Work; contaminated water; design; experience; externship; improved; innovative technologies; inorganic phosphate; next generation; portability; remediation; solute; water treatment

KC Donnelly Abstract for Francisco Leniz PD/PI: Kelly Pennell Abstract The challenge of providing drinkable water to the world population, and its close relation to the need of purifying natural water from contaminants has been present throughout the history of the humankind. As part of the Project 3 at the UKSRC, “Responsive Membranes and Advanced Materials for Sensing and Remediation of Halo-organics”, we have been working on the development of multifunctional materials toward the increase of separation rates, more energy efficient, and portable technologies. Per- and polyfluoroalkyl substances (PFAS) were our case of study in our previous manuscript. Bringing together Project 3 at the UKSRC and Project 4 from MEMCARE at Yale University, “Designing the next generation of highly selective sorbents for water remediation”, means merging teams' efforts with a common goal, the remediation of water for the society. Recently, Project 4 from MEMCARE has focused on developing selective adsorbents for the separation of Arsenic in water from non-contaminant competitors. Our knowledge on synthesis of multifunctional platform can provide intriguing opportunities for the integration of these adsorbents. Overall, this experience will expand my understanding of separation technologies and the transport mechanisms of solutes through these, for the application of a broader range of contaminants in water, from organic to inorganic anions. The pore-functionalized adsorptive nanofiltration membranes, with the integration of highly selective adsorbents, is hypothesized to bring new high separation rates in a more compact fashion, which can benefit people and communities by easing the portability of this technology.

KC Donnelly为Francisco Leniz PD/PI撰写摘要：Kelly Pennell 摘要 向世界人口提供饮用水的挑战及其与 在整个人类历史上，净化天然水中的污染物一直存在。AS UKSRC项目3的一部分，“响应膜和先进的传感和材料” 修复卤代有机物“，我们一直致力于多功能材料的开发 朝着分离率的提高、更节能和便携技术的方向发展。每和 多氟烷基物质(PFAS)是我们在以前的手稿中研究的案例。汇聚在一起 UKSRC的项目3和耶鲁大学MEMCARE的项目4，《设计下一个 用于水修复的高选择性吸附剂的产生“，意味着将团队的努力与 共同的目标，水的修复为社会。最近，来自MEMCARE的项目4专注于 水中砷与无公害分离用选择性吸附剂的研制 竞争对手。我们在合成多功能平台方面的知识可以提供有趣的机会 用于整合这些吸附剂。总体而言，这次经历将扩大我对 分离技术和溶质在这些分离技术中的传输机制 水中的污染物范围更广，从有机阴离子到无机阴离子。孔功能化 假设吸附纳滤膜集成了高选择性的吸附剂。 以更紧凑的方式带来新的高离婚率，这将造福于人民和社区 通过简化这项技术的可移植性。