Developing capacity for planning and adapting to riverbank erosion and its consequences in the Yukon River Basin

发展育空河流域规划和适应河岸侵蚀及其后果的能力

• 批准号: 2127442
• 负责人: Michael Lamb
• 金额: $ 137.7万
• 依托单位: California Institute of Technology
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-01-01 至 2026-12-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2127442&HistoricalAwards=false
• 关键词: Developing; capacity; planning; adapting; riverbank

Navigating the New Arctic (NNA) is one of NSF's 10 Big Ideas. NNA projects address convergence scientific challenges in the rapidly changing Arctic. The Arctic research is needed to inform the economy, security and resilience of the Nation, the larger region and the globe. NNA empowers new research partnerships from local to international scales, diversifies the next generation of Arctic researchers, enhances efforts in formal and informal education, and integrates the co-production of knowledge where appropriate. This award fulfills part of that aim by addressing interactions among social systems, natural environment, and built environment in the following NNA focus areas: Arctic Residents, Data and Observation, Forecasting, Global Impact, and Resilient Infrastructure. Arctic warming is causing landscape change that is affecting Arctic communities. Rivers and floodplains are particularly susceptible to a warmer climate due to permafrost thaw that can lead to accelerated erosion. This erosion threatens critical infrastructure and disrupts community life, including by sometimes displacing entire Alaska communities. Yet the response of erosion to warming, and its implications, are not well understood. In addition to imperiling infrastructure, erosion exposes frozen floodplain sediment that contains potential contaminants including heavy metals, such as mercury, along with nutrients and pathogens, all of which can imperil water quality and ecosystem health. By affecting community infrastructure and water quality, Arctic river erosion sits at the nexus of multiple problems that impact society. Greater understanding of bank erosion and its water quality impacts will be critical to supporting sustainable Arctic communities. Equally important will be understanding regional adaptive capacity challenges and opportunities to allow for the adoption of scientific knowledge into actionable plans and policies. To meet these multiple challenges important for scientific knowledge and society, this project unites a research team from the Yukon River Inter-Tribal Watershed Council, University of Alaska Anchorage, California Institute of Technology, Los Alamos National Laboratory, University of Southern California, and three Indigenous partner communities in the Yukon River basin that are threatened by riverbank erosion.The project will develop numerical models of landscape evolution to understand rates of riverbank erosion in the warming Arctic and their effects on biogeochemical processes that affect water quality and community infrastructure. Observational stations will monitor bank erosion, flow hydraulics, water quality and microbial ecosystems at three study sites co-located with partner communities in the Yukon River basin. Floodplain, riverbank and water column sampling will be used with biogeochemical, isotopic and metagenomic measurements to understand the abundance, character and process dynamics of fine sediment, nutrients, mercury and other metals, and pathogens. The project also will include an evaluation of regional adaptive capacity and an identification of opportunities for and institutional barriers to adaptation. Natural and social science will converge to produce Erosion Action Plans that are needed for Alaska Native communities to plan for climate-change adaptation. Community-based science will enhance this collaborative effort, and educational activities with our partner communities will build and fortify process understanding. Web-based modules will illustrate and inform the public about observed changes in Arctic rivers, future projections, and how new science combined with citizen-science efforts can lead to effective planning strategies for sustainable Arctic communities.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.

新北极航行（NNA）是NSF的十大创意之一。NNA项目解决快速变化的北极地区的趋同科学挑战。北极研究需要为国家、更大地区和地球仪的经济、安全和复原力提供信息。NNA授权从地方到国际规模的新的研究伙伴关系，使下一代北极研究人员多样化，加强正规和非正规教育的努力，并在适当的情况下整合知识的共同生产。该奖项通过解决以下NNA重点领域的社会系统，自然环境和建筑环境之间的相互作用实现了这一目标的一部分：北极居民，数据和观测，预测，全球影响和弹性基础设施。北极变暖正在导致影响北极社区的景观变化。河流和洪泛平原特别容易受到气候变暖的影响，因为永久冻土融化可能导致加速侵蚀。这种侵蚀威胁到关键的基础设施，扰乱了社区生活，有时甚至使整个阿拉斯加社区流离失所。然而，侵蚀对变暖的反应及其影响还没有得到很好的理解。除了危及基础设施外，侵蚀还暴露了冰冻的洪泛区沉积物，其中含有潜在的污染物，包括汞等重金属，沿着营养物质和病原体，所有这些都可能危及水质和生态系统健康。通过影响社区基础设施和水质，北极河流侵蚀是影响社会的多种问题的核心。更好地了解河岸侵蚀及其对水质的影响对于支持可持续的北极社区至关重要。同样重要的是了解区域适应能力的挑战和机遇，以便将科学知识纳入可采取行动的计划和政策。为了应对这些对科学知识和社会至关重要的多重挑战，该项目联合了来自育空地区河部落间流域理事会、阿拉斯加大学安克雷奇分校、加州理工学院、洛斯阿拉莫斯国家实验室、南加州大学、以及育空地区河流域受到河岸侵蚀威胁的三个土著伙伴社区。该项目将开发景观数字模型，气候变化的演变，以了解在变暖的北极河岸侵蚀率及其对影响水质和社区基础设施的生态地球化学过程的影响。观测站将在育空地区河流域与伙伴社区同处的三个研究地点监测河岸侵蚀、水流水力学、水质和微生物生态系统。洪泛区、河岸和水柱取样将与生物地球化学、同位素和宏基因组测量一起使用，以了解细沉积物、营养物、汞和其他金属以及病原体的丰度、特征和过程动态。该项目还将包括对区域适应能力的评价，并查明适应的机会和体制障碍。自然科学和社会科学将结合起来，制定阿拉斯加原住民社区规划气候变化适应所需的侵蚀行动计划。以社区为基础的科学将加强这种合作努力，与我们的合作伙伴社区的教育活动将建立和加强对过程的理解。基于网络的模块将说明并告知公众北极河流的观测变化，未来预测，以及新科学与公民科学的努力如何结合，为可持续的北极社区带来有效的规划战略。该奖项反映了NSF的法定使命，并被认为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来支持。

项目成果

Arctic Permafrost Thawing Enhances Sulfide Oxidation

• DOI: 10.1029/2022gb007644
• 发表时间: 2023-09
• 期刊: Global Biogeochemical Cycles
• 影响因子: 5.2
• 作者: P. Kemeny;Gen K. Li;M. Douglas;W. Berelson;A. Chadwick;N. Dalleska;M. Lamb;William Larsen;J. Magyar;N. Rollins;J. Rowland;M. Smith;Mark A. Torres;Samuel M. Webb;Woodward W. Fischer;A. J. West

Sediment Entrainment and Slump Blocks Limit Permafrost Riverbank Erosion

泥沙夹带和塌落块限制了永久冻土河岸侵蚀

• DOI: 10.1029/2023gl102974
• 发表时间: 2023
• 期刊: Geophysical Research Letters
• 影响因子: 5.2
• 作者: Douglas, Madison M.;Dunne, Kieran B. J.;Lamb, Michael P.
• 通讯作者: Lamb, Michael P.

Scale‐Dependent Influence of Permafrost on Riverbank Erosion Rates

• DOI: 10.1029/2023jf007101
• 发表时间: 2023-07
• 期刊: Journal of Geophysical Research: Earth Surface
• 作者: J. Rowland;Jon Schwenk;E. Shelef;J. Muss;Daniela Ahrens;S. Stauffer;Anastasia Pilliouras;B. Crosby;A. Chadwick;M. Douglas;P. Kemeny;M. Lamb;Gen K. Li;L. Vulis