Collaborative Research: CAS-Climate: Nonstationarity of Compound Coastal Floods in the Anthropocene

合作研究：CAS-气候：人类世复合沿海洪水的非平稳性

• 批准号: 2223894
• 负责人: David Muñoz
• 金额: $ 7.98万
• 依托单位: Virginia Polytechnic Institute and State University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-10-01 至 2025-09-30
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2223894&HistoricalAwards=false
• 关键词: Collaborative; Research; CAS; Climate; Nonstationarity

Human activities, such as hydrologic regulations and altered land-cover land-use (i.e., urbanization and deforestation) directly modulate freshwater regime to lower coastal regions. Large-scale anthropogenic activities also contribute to global warming, which drives sea level rise (SLR) and intensifies the magnitude of natural hazards (i.e., hurricanes). These terrestrial and coastal hazard drivers synergize to produce compound floods through nonlinear interactions that yield in a level of risk not expected from each driver in isolation. Yet, the spatiotemporal variability of these nonstationary processes and the associated risks are not well understood. Compounding flood patterns are responsible for many of the recent hydroclimate disasters (i.e. hurricanes Harvey, Maria, and Ida), and are expected to evolve under anthropogenic effects. This project helps provide a solid operational framework for hydrologists and coastal planners that can be used for quantifying the expected impacts of coastal hydrology stressors on coastal communities and ecosystems, thereby facilitating efficient resource allocation for risk mitigation in the face of SLR and rapid urbanization. This project will support a suite of educational and awareness activities, which will utilize and enhance programs already in existence at The University of Alabama, particularly those to recruit students from diverse backgrounds that are not well represented in STEM fields. This project creates a fundamental body of knowledge on the ever-changing physical and statistical dependence among various compound flooding drivers over time (e.g., river flow, rainfall and coastal sea level) and advances our understanding on how such a nonstationary dependence affects the flooding dynamics and the associated risks. The team will develop a Hybrid Statistical-Process Based modeling framework that integrates statistical tools for nonstationary multivariate data analysis, machine learning algorithms and coupled hydrologic-hydrodynamic models for probabilistic flood inundation mapping. This project is co-funded by a collaboration between the Directorate for Geosciences and the Office of Advanced Cyberinfrastructure to support AI/ML and open science activities in the geosciences.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.

人类活动，如水文调节和土地覆盖土地利用变化(即城市化和砍伐森林)，直接将淡水状况调整到较低的沿海地区。大规模的人为活动也加剧了全球变暖，导致海平面上升，加剧了自然灾害(即飓风)的严重程度。这些陆地和沿海灾害驱动因素协同作用，通过非线性相互作用产生的风险水平不是每个单独驱动因素所预期的，从而产生复合洪水。然而，这些非平稳过程的时空变异性及其相关风险还没有得到很好的理解。复合洪水模式是最近许多水气候灾害(即飓风哈维、玛丽亚和艾达)的罪魁祸首，预计将在人为影响下演变。该项目有助于为水文学家和沿海规划者提供一个可靠的业务框架，可用于量化沿海水文压力对沿海社区和生态系统的预期影响，从而促进在面临可持续发展和快速城市化的情况下有效分配资源以减少风险。该项目将支持一系列教育和宣传活动，这些活动将利用和加强阿拉巴马大学现有的项目，特别是那些招收在STEM领域没有很好代表的不同背景的学生的项目。该项目建立了关于各种复合洪灾驱动因素(如河流流量、降雨量和沿海海平面)随时间变化的物理和统计相关性的基本知识体系，并促进了我们对这种非平稳相关性如何影响洪灾动态和相关风险的理解。该团队将开发一个基于混合统计过程的建模框架，该框架集成了用于非平稳多变量数据分析的统计工具、机器学习算法和用于概率洪水淹没制图的水文-水动力学耦合模型。该项目由地球科学局和高级网络基础设施办公室共同资助，以支持AI/ML和地球科学领域的开放科学活动。该奖项反映了NSF的法定使命，并通过使用基金会的智力优势和更广泛的影响审查标准进行评估，被认为值得支持。