Collaborative Research: GCR: Convergence on Phosphorus Sensing for Understanding Global Biogeochemistry and Enabling Pollution Management and Mitigation

合作研究：GCR：融合磷传感以了解全球生物地球化学并实现污染管理和缓解

• 批准号: 2317823
• 负责人: Satoshi Ishii
• 金额: $ 78.89万
• 依托单位: University of Minnesota-Twin Cities
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2023
• 资助国家: 美国
• 起止时间: 2023-10-01 至 2028-09-30
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2317823&HistoricalAwards=false
• 关键词: Collaborative; Research; GCR; Convergence; Phosphorus

Phosphorus (P) is an essential element that forms the basis for all life on earth. Phosphorus plays a central role in biogeochemical cycles that broadly impact global biological productivity, food resources, energy generation, and climate. Understanding the complex interrelationships between critical food, energy, and water resources and addressing phosphorus demand, pollution, and recovery are some of the greatest scientific challenges for a sustainable future. At the root of these problems is the inability to measure phosphorus directly when and where one would like and to do so in a cost-effective manner. This technology gap precludes the ability to close the “phosphorus cycle” at regional, national, and global scales. This Growing Convergence Research project will overcome fundamental science, engineering, and prototyping challenges to enable portable, low-cost, robust, and selective sensors for phosphorus that address these critical and unmet needs. This project brings together researchers with expertise spanning supramolecular and inorganic chemistry, polymer science, soft-matter electronics, electrical engineering, and environmental and marine science. Convergent scientific, technological, and engineering advances will coalesce to realize new paradigms for control at the chemical, supramolecular, transduction, and device levels that will ultimately serve as the basis for ushering in a completely new generation of sensors for phosphorus. These sensors will satisfy the functional and economic requirements needed to provide pragmatic solutions for capturing the complexity of how phosphorus exists in space and time within agricultural landscapes, waterways, and ecosystems. Engagements with stakeholders, industrial partners, and government agencies will guide efforts towards additional applications, commercialization, and other societally relevant sensing challenges.This convergent research program will integrate basic science and engineering approaches together and combine significant intellectual and technical overlap between traditionally disparate disciplines to address long-standing challenges that have limited the development of phosphorus sensing technologies. Specific objectives of the program are to: (1) design, develop and understand how molecular recognition elements (“receptors”) selectively bind phosphorus in the form of inorganic and organic phosphate compounds, (2) tailor receptor-analyte-semiconductor interactions and investigate how they specifically transduce the phosphate-binding events into a sensitive signal; (3) integrate these chemistries within low-cost electronic devices; (4) engineer sensors that enable sensitive quantification in complex environments for managing the phosphorus cycle including agricultural runoff, wastewater, and fresh, brackish, estuarine, and marine environments; (5) communicate chemical phosphate detection to electronic platforms to digitize and relay this data; and (6) develop prototypes for field use and demonstrations. This holistic approach will produce field-deployable technologies for phosphorus that are low-cost, operate in real-time, and directly interface with commercial platforms broadly utilized within agricultural, environmental, and marine monitoring.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

磷（P）是地球上所有生命的基本元素。磷在地球化学循环中发挥着核心作用，广泛影响全球生物生产力，粮食资源，能源生产和气候。了解关键粮食、能源和水资源之间的复杂相互关系，解决磷的需求、污染和恢复问题，是实现可持续未来的最大科学挑战。这些问题的根源是无法在人们希望的时间和地点直接测量磷，并且无法以具有成本效益的方式这样做。这一技术差距阻碍了在区域、国家和全球范围内关闭“磷循环”的能力。这个不断增长的融合研究项目将克服基础科学，工程和原型设计的挑战，使便携式，低成本，强大的和选择性的磷传感器，以解决这些关键和未满足的需求。该项目汇集了具有超分子和无机化学，聚合物科学，软物质电子，电气工程以及环境和海洋科学专业知识的研究人员。科学、技术和工程的融合进步将结合起来，实现化学、超分子、转导和设备水平的新控制范式，这些范式最终将成为开创全新一代磷传感器的基础。这些传感器将满足功能和经济要求，为捕获农业景观，水道和生态系统中磷在空间和时间上的复杂性提供实用的解决方案。与利益相关者，工业合作伙伴和政府机构的参与将引导更多的应用，商业化和其他社会相关的传感challenges.This融合的研究计划将整合基础科学和工程方法在一起，联合收割机之间的传统不同学科的重大知识和技术重叠，以解决长期存在的挑战，限制了磷传感技术的发展。该计划的具体目标是：（1）设计，开发和了解分子识别元件（“受体”）以无机和有机磷酸盐化合物的形式选择性地结合磷，（2）定制受体-分析物-半导体相互作用并研究它们如何特异性地将磷酸盐结合事件转化为敏感信号;（3）将这些化学物质集成在低成本电子器件中;（4）设计传感器，使其能够在复杂环境中进行灵敏的量化，以管理磷循环，包括农业径流、废水以及淡水、半咸水、河口和海洋环境;（5）将化学磷酸盐检测传送到电子平台，以监测和传递该数据;以及（6）开发用于现场使用和演示的原型。这一整体方法将产生低成本、实时操作、直接与农业、环境和海洋监测中广泛使用的商业平台接口的可现场部署的磷技术。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。