CAREER: Land-Atmosphere Coupling and Feedback in the Context of Climate Change

职业：气候变化背景下的陆地-大气耦合和反馈

• 批准号: 2239877
• 负责人: Darren Drewry
• 金额: $ 61.73万
• 依托单位: Ohio State University
• 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: 2023-09-01 至 2028-08-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2239877&HistoricalAwards=false
• 关键词: CAREER; Land; Atmosphere; Coupling; Feedback

The interactions between the terrestrial land surface and the atmosphere are central to the Earth’s surface water, energy and carbon budgets. These interactions control a wide range of processes with a direct impact on humanity, including near-surface climate variability, cloud formation and precipitation. Land-atmosphere processes remain a significant challenge in large-scale weather and climate prediction due to their inherent complexity and the trans-disciplinary approach required to study them. Likewise, human activities that shape terrestrial landscapes such as deforestation and agricultural production directly impact the atmosphere in which they exist, resulting in the feedback of land surface functioning onto the surface conditions that are experienced. These interactions are rooted in the structure and function of the vegetation-soil systems at the land surface, and the ecological responses of these systems to atmospheric forcing. This project will integrate the development of novel high-resolution computer modeling tools and data analytical approaches with the rich information on plant responses to climate developed over decades of field system manipulation experiments to advance our understanding of how land-atmosphere interactions will evolve over the coming decades. This CAREER project will contribute to the development of the next generation of scientists and engineers who are technically equipped and motivated to study complex environmental systems to enable a sustainable future. The broader impacts of this project combine inter-disciplinary training of students at the undergraduate and graduate level with outreach programs serving underrepresented groups in STEM at the high school level.This award will advance our fundamental understanding of land-atmosphere interactions and feedback by: (1) developing high-fidelity 3D modeling tools for high-spatial and temporal resolution of land-atmosphere exchange processes and their consequent impacts on atmospheric development and land surface response; (2) utilizing new analytical approaches to diagnose land-atmosphere coupling and feedback in high resolution simulation output; (3) applying this new simulation platform to climate change scenarios across multiple vegetation and geographic domains. High resolution simulations of recent land-atmosphere interaction field campaigns will allow for validation of the simulation framework against observations of land-atmosphere carbon, water, energy and momentum fluxes, near surface climate variation, atmospheric boundary layer structure and cloud formation. Novel statistical tools will be used to quantify information flow, directionality and explicitly quantify feedback between surface and atmospheric states and fluxes. These tools will be used to analyze a suite of simulations designed to quantify the relative roles of vegetation structure, physiological and biochemical function, atmospheric state and the structure of the lower atmosphere on emergent land-atmosphere interactions and feedbacks. Overall this CAREER project will lead to a better understanding of how and why land-atmosphere interactions will change in the coming decades.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.

陆地表面与大气之间的相互作用是地球表面水、能源和碳收支的核心。这些相互作用控制着一系列直接影响人类的过程，包括近地表气候变异、云的形成和降水。陆气过程由于其固有的复杂性和研究所需的跨学科方法，仍然是大尺度天气和气候预测中的一个重大挑战。同样，人类的毁林和农业生产等塑造陆地景观的活动直接影响到它们所处的大气层，导致陆地表面功能对所经历的表面条件的反馈。这些相互作用植根于地表植被-土壤系统的结构和功能，以及这些系统对大气强迫的生态响应。该项目将把新型高分辨率计算机建模工具和数据分析方法的开发与几十年来田间系统操作实验中开发的植物对气候反应的丰富信息相结合，以促进我们对未来几十年陆地-大气相互作用将如何演变的理解。这个职业生涯项目将有助于下一代科学家和工程师的发展，他们在技术上装备精良，有动力研究复杂的环境系统，以实现可持续的未来。该项目的更广泛的影响结合了联合收割机跨学科培训的学生在本科和研究生的水平与外展计划，服务于代表性不足的群体在干在高中水平.这个奖项将通过以下方式推进我们的土地-大气相互作用和反馈的基本理解：（1）开发高空间和时间分辨率的高保真三维建模工具，大气交换过程及其对大气发展和陆面响应的影响：（2）利用新的分析方法诊断陆-气耦合，并在高分辨率模拟输出中进行反馈;（3）将这一新的模拟平台应用于跨多个植被和地理区域的气候变化情景。对近期陆-气相互作用实地活动的高分辨率模拟将允许对照陆-气碳、水、能量和动量通量、近地面气候变化、大气边界层结构和云形成的观测结果验证模拟框架。新的统计工具将用于量化信息流、方向性，并明确量化地表和大气状态和通量之间的反馈。这些工具将用于分析一套模拟，这些模拟旨在量化植被结构、生理和生化功能、大气状态和低层大气结构对紧急陆-气相互作用和反馈的相对作用。总的来说，这个CAREER项目将导致更好地了解如何以及为什么陆地-大气相互作用将在未来几十年发生变化。这个奖项反映了NSF的法定使命，并已被认为是值得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的支持。