The impacts of rapidly receding glaciers on proglacial freshwater resources and ecological services

冰川快速消退对冰前淡水资源和生态服务的影响

• 批准号: RGPIN-2019-04272
• 负责人: StLouis, Vincent
• 金额: $ 1.82万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=744835
• 关键词: impacts; rapidly; receding; glaciers; proglacial

Human-induced climate change is the most pressing environmental issue of our time, threatening the security of our water and food supply, ecosystem and human health, and socioeconomic wellness. Indeed, access to clean freshwater, and the natural goods and services it provides, is a fundamental human right. Glaciers provide essential freshwater to more than a sixth of the world's population, yet climate warming is resulting in a decline of global glacier volume, with coincident changes to downstream runoff. Lowering greenhouse gas emissions to preserve our remaining glaciers and river flows is vital for ensuring some level of global water security. However, it is equally essential to quantify the changes in glaciological, biogeochemical, and limnological processes that are already occurring in the rapidly evolving proglacial landscapes forming in front of retreating glaciers. Assessing these changes will allow us to understand how glacial retreat will influence freshwater quality and ecosystem function further downstream, where most of the human population lives and works. For example, loss of glacial mass may result in the large releases of nutrients, ancient organic carbon and contaminants historically archived in glacial ice and buried beneath glaciers, all of which could impact downstream freshwater quality, productivity, resources and ecological services. In contrast, as glacial rivers cross newly-emerged proglacial landscapes, they may actually consume atmospheric carbon dioxide (CO2) via chemical weathering of some of the abundantly available freshly comminuted fine-grained minerals they entrain. As such, there are four objectives to my proposed research program, each aligning with a graduate student project, and additional training of undergraduate students, Inuit and other northern peoples, and laboratory technicians: (1) characterize the geochemical processes that consume CO2 in proglacial rivers and lakes; (2) determine the global extent of this CO2 consumption; (3) quantify biological productivity in proglacial lakes; and (4) quantify seasonal, interannual and spatial patterns in global proglacial freshwater chemistry. This innovative, interdisciplinary, and collaborative research and training program will have two major scientific impacts: it will (1) enhance our understanding of regional and global CO2 budgets (Objectives 1 and (2) improve our knowledge of regional and global proglacial freshwater quality and services (Objectives 3&4). From a more socio-economic perspective, this research will increase our ability to predict the impact of climate change on the quality of surface water-a resource that is vital for basic food and drinking water security. Indeed, the traditional lifestyles of many human populations around the globe rely on the crucial and highly vulnerable freshwater resources that originate from glaciers. Therefore, increasing our knowledge of these resources, and how they may change in the future, is critical.

人类引起的气候变化是我们这个时代最紧迫的环境问题，威胁着我们的水和食物供应、生态系统和人类健康以及社会经济福祉的安全。事实上，获得清洁淡水及其提供的自然产品和服务是一项基本人权。冰川为世界六分之一以上的人口提供了必要的淡水，但气候变暖正在导致全球冰川体积的减少，下游径流也随之发生变化。减少温室气体排放以保护我们剩余的冰川和河流对于确保某种程度的全球水安全至关重要。然而，同样重要的是量化冰川学、地球化学和湖沼学过程的变化，这些变化已经发生在冰川退缩前形成的快速演变的冰前景观中。评估这些变化将使我们了解冰川退缩将如何影响下游的淡水质量和生态系统功能，而大多数人口都在下游生活和工作。例如，冰川物质的损失可能导致大量的营养物质、古有机碳和历史上储存在冰川中并埋在冰川下的污染物的释放，所有这些都可能影响下游的淡水质量、生产力、资源和生态服务。相比之下，当冰川河流穿越新出现的冰川前景观时，它们实际上可能会通过化学风化它们夹带的一些丰富的新鲜粉碎的细粒矿物来消耗大气中的二氧化碳（CO2）。因此，我提出的研究计划有四个目标，每个目标都与研究生项目相一致，并对本科生、因纽特人和其他北方人以及实验室技术人员进行额外的培训：（1）描述冰前河流和湖泊中消耗CO2的地球化学过程;（2）确定这种CO2消耗的全球范围;（3）量化冰前湖泊的生物生产力;以及（4）量化全球冰前淡水化学的季节、年际和空间格局。这一创新的、跨学科的、合作的研究和培训项目将产生两大科学影响：（1）提高我们对区域和全球二氧化碳预算的理解（目标1和2）提高我们对区域和全球冰川前淡水质量和服务的认识（目标3和4）。从更社会经济的角度来看，这项研究将提高我们预测气候变化对地表水质量影响的能力，地表水是一种对基本食品和饮用水安全至关重要的资源。事实上，地球仪上许多人的传统生活方式依赖于来自冰川的重要和非常脆弱的淡水资源。因此，增加我们对这些资源的了解，以及它们在未来可能如何变化，至关重要。