Linking carbon to structure and function in aquatic ecosystems

将碳与水生生态系统的结构和功能联系起来

• 批准号: RGPIN-2019-04468
• 负责人: Xenopoulos, Marguerite
• 金额: $ 4.01万
• 依托单位: Trent University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=690585
• 关键词: Linking; carbon; structure; function; aquatic

Freshwater ecosystems are biogeochemical hotspots that play an important role in the global carbon cycle especially in relation to their relatively small geographic footprint. The rates at which lakes and rivers respire carbon (“metabolism”) is a key characteristic of these ecosystems. A central piece of the freshwater metabolism puzzle is dissolved organic matter (DOM), due to its very high prevalence and mobility across the landscape (from land to sea). DOM serves as a substrate for microbes, affects the light environment, and controls diverse food web and ecosystem processes in freshwater ecosystems. While DOM quantity has been recognized to be a central determinant of many lake and river properties, it is becoming increasingly clear that not all DOM is chemically equivalent and that its chemical composition (its quality) varies within and among aquatic ecosystems. In this project, I will examine how DOM quantity and quality is affected by nutrients and how, in turn, DOM quality and nutrients regulate ecological function in streams, rivers and lakes. Through a series of field surveys and experiments we will assess sources of DOM, determine pathways of DOM movement and loss, and understand patterns of DOM quality as they relate to nutrients in freshwater ecosystems through time and space. This information on the biogeochemical controls of carbon transformations and fluxes is integral to understanding the effects of global change and land use change on freshwater ecosystems across landscapes. My research team will include at least 15 highly diverse students that I will mentor to complete multidisciplinary research theses that can include principles of ecosystem ecology, water chemistry, biological activity, hydrological transport and mathematics. Finally, their research theses can provide information to management agencies on DOM, its interaction with nutrients, its retention in aquatic systems and its effects on ecological function with significant implications for ecosystem health and ecosystem services (e.g., recreation, drinking water, eutrophication).

淡水生态系统是生物地球化学热点，在全球碳循环中发挥着重要作用，特别是因为其地理足迹相对较小。湖泊和河流呼吸碳的速率（“新陈代谢”）是这些生态系统的一个关键特征。溶解有机物（DOM）是淡水代谢难题的核心部分，因为它在整个景观（从陆地到海洋）中具有非常高的流行性和流动性。DOM作为微生物的底物，影响光环境，并控制淡水生态系统中的各种食物网和生态系统过程。虽然人们已经认识到，DOM的数量是许多湖泊和河流特性的核心决定因素，但越来越清楚的是，并非所有DOM都具有化学等效性，其化学组成（质量）在水生生态系统内部和之间存在差异。在这个项目中，我将研究DOM的数量和质量如何受到营养物质的影响，以及DOM的质量和营养物质如何调节溪流，河流和湖泊的生态功能。通过一系列的实地调查和实验，我们将评估DOM的来源，确定DOM的运动和损失的途径，并了解DOM质量的模式，因为它们与淡水生态系统中的营养物质通过时间和空间。这种关于碳转化和通量的生物地球化学控制的信息对于理解全球变化和土地利用变化对各种景观的淡水生态系统的影响是不可或缺的。我的研究团队将包括至少15名高度多样化的学生，我将指导他们完成多学科研究论文，其中包括生态系统生态学，水化学，生物活性，水文运输和数学的原理。最后，他们的研究论文可以为管理机构提供有关DOM的信息，其与营养物质的相互作用，其在水生系统中的保留及其对生态功能的影响，对生态系统健康和生态系统服务具有重要意义（例如，娱乐、饮用水、富营养化）。