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BE/CNH: Understanding Linkages Among Human and Biogeochemical Processes in Agricultural Landscapes

BE/CNH：了解农业景观中人类和生物地球化学过程之间的联系

基本信息

批准号：
0508028
负责人：
Laurie Drinkwater
金额：
$ 160万
依托单位：
Cornell Univ - State: AWDS MADE PRIOR MAY 2010
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2005
资助国家：
美国
起止时间：
2005-09-01 至 2011-09-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=0508028&HistoricalAwards=false
关键词：
CNH Understanding Linkages Among Human

项目摘要

Humans have profoundly altered global cycling processes at multiple scales. Current estimates suggest human activities have doubled the amount of biologically active nitrogen on a global basis, with agriculture accounting for 75 percent of the human-derived nitrogen. A complex set of environmental and socio-economic factors influence agricultural fertilizer management practices. Linkages among socioeconomic and ecological subsystems are recognized as crucial in efforts to pursue sustainable ecosystem management and improve nitrogen-use efficiency. Disconnections between human and natural subsystems must be addressed as well as disconnections within the component subsystems. Within the human realm, those who pollute do not pay the costs associated with resource degradation. Likewise, the biophysical system that has evolved as a result of high, input industrial agriculture is fraught with ecological disconnections. For example, uncoupling of carbon and nitrogen cycles is a defining trait of agricultural systems and is the root cause of the leakiness of these systems. On average, 45 percent to 55 percent of fertilizer nitrogen applied is lost to the environment. The goal of this research project is to understand how interactions among social and biophysical subsystems impact on carbon and nitrogen cycles in intensively managed agricultural landscapes at multiple scales. Specific objectives of the project are (1) to investigate how the human subsystem responds to the environmental consequences of carbon nitrogen uncoupling, (2) to evaluate the relationships between nitrogen leakiness, institutional capacity, and proximity to degraded aquatic resources, (3) to determine which policy changes are likely to be most effective in promoting more efficient nitrogen fertilizer-management practices, and (4) to model and simulate multi-scale interactions among policies, farm managers, and institutions as well as nitrogen losses across space and time. To understand how institutions respond to degradation of aquatic ecosystems, the investigators will compare the institutions and management approaches used in the Chesapeake Bay, where the negative impacts of excess nitrogen inputs are experienced more locally and by the farmers themselves, to those in the Midwest, where the negative impacts are much more remote. Research methods include field research, isotopic tracer studies, construction of mass balances at multiple scales, face-to-face interviews and surveys with stakeholders, geographical information systems, remote sensing, global positioning systems, statistical tools, systems modeling, and simulation.This project has implications for coupled human-natural systems theory and methodology, social systems theory, and environmental policy. The theory of how the human and biophysical subsystems of managed landscapes is not well developed, particularly in the case of intensively managed, high-input agricultural systems. This research will enhance fundamental understanding of how social and ecosystem emergent properties mediate interactions among human and natural systems. In addition to using a synthetic interdisciplinary approach, the investigators will depart from a microeconomic model of social dynamics in which the aggregated behavior of individual actors is taken to represent social processes. They will focus primarily at the institutional level, where the social emergent properties govern the interactions between and social and natural subsystems. The project also will have practical outcomes of relevance to the development of agricultural and resource-management policy. This project is supported by an award resulting from the FY 2005 special competition in Biocomplexity in the Environment focusing on the Dynamics of Coupled Natural and Human Systems.

人类在多个尺度上深刻改变了全球循环过程。目前的估计表明，人类活动使全球生物活性氮的数量翻了一番，农业占人类来源氮的75%。一系列复杂的环境和社会经济因素影响着农业肥料管理实践。人们认识到，社会经济和生态子系统之间的联系对于努力实现可持续生态系统管理和提高氮的使用效率至关重要。必须解决人类和自然子系统之间的断开以及组件子系统内部的断开。在人类领域，那些污染者并不为资源退化付出代价。同样，由于高投入的工业化农业而演变的生物物理系统充满了生态脱节。例如，碳和氮循环的脱钩是农业系统的一个决定性特征，也是这些系统泄漏的根本原因。平均而言，45%至55%的肥料氮流失到环境中。该研究项目的目标是了解社会和生物物理子系统之间的相互作用如何影响碳和氮循环在集约管理的农业景观在多个尺度。该项目的具体目标是：（1）调查人类子系统如何对碳氮解偶联的环境后果作出反应，（2）评估氮泄漏、机构能力和接近退化水生资源之间的关系，（3）确定哪些政策变化可能最有效地促进更有效的氮肥管理实践，以及（4）模拟和模拟政策、农场管理者和机构之间的多尺度相互作用以及跨空间和时间的氮素损失。为了了解机构如何应对水生生态系统的退化，研究人员将比较切萨皮克湾使用的机构和管理方法，在那里，过量氮投入的负面影响更多地体现在当地和农民自己身上，而在中西部，负面影响要远得多。研究方法包括实地调查、同位素示踪研究、多尺度质量平衡的构建、与利益相关者的面对面访谈和调查、地理信息系统、遥感、全球定位系统、统计工具、系统建模和模拟。该项目对耦合人类-自然系统理论和方法、社会系统理论和环境政策具有影响。关于管理景观的人类和生物物理子系统如何发展的理论还没有很好地发展，特别是在集约管理、高投入的农业系统的情况下。这项研究将加强对社会和生态系统新兴特性如何介导人类和自然系统之间相互作用的基本理解。除了使用综合跨学科的方法，研究人员将离开社会动态的微观经济模型，其中个体行为者的聚合行为被用来代表社会过程。他们将主要集中在制度层面，在那里的社会涌现属性管理社会和自然子系统之间的相互作用。该项目还将产生与制定农业和资源管理政策有关的实际成果。该项目得到了2005财政年度环境中生物复杂性特别竞赛的支持，该竞赛侧重于自然和人类系统耦合的动力学。