Organic carbon cycling along high-latitude continental margins and implications of climate change

高纬度大陆边缘的有机碳循环及气候变化的影响

• 批准号: RGPIN-2019-05874
• 负责人: Kuzyk, ZouZou
• 金额: $ 1.82万
• 依托单位: University of Manitoba
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=715034
• 关键词: Organic; carbon; cycling; along; latitude

The carbon cycle involves the atmosphere, land and ocean and influences global climate. Organic carbon (OC) is the portion associated with living or dead matter; produced by plants from CO2, transformed by microbes and animals, and remineralized back to CO2 by respiration, degradation etc. Continental margins (nearshore zones and shelves) are important sites of OC cycling. They receive OC from both the land and the ocean and its production and destruction makes them sites of dynamic CO2 exchange with the atmosphere. Continental margins also receive sediment from rivers and coastal erosion, which promotes burial (sequestration) of OC. About 75% of the world's population lives along margins and their ecosystem services are worth $25 trillion annually. High-latitude areas are experiencing rapid climate change, including loss of sea ice, altered river runoff and thawing permafrost. The OC cycle will thus be affected by changes in sources and altered processing of OC in warmer, fresher, more ice-free, and possibly more productive coastal waters. Food webs will be impacted by these changes, as will CO2 exchange. One of the largest unknowns is how old terrigenous carbon will contribute to change. This carbon has been locked up in subsurface soils and permafrost for thousands of years, but is released when permafrost thaws and can be remineralized to CO2 in margin areas, particularly when highly-degradable marine OC exerts a priming effect'. Because there is a very large amount of old terrigenous OC, its degradation represents a significant potential feedback to climate change. The overall objective of this proposed Discovery program is to improve our understanding of the processes that determine the fate of terrigenous OC along high-latitude continental margins. Some of these processes occur in the water column and some in surface sediments. Because the margin is variable in space and time, we will focus on “hot spots” and “hot moments”, conducting field studies along i) dynamic, river-dominated open shelf areas, where we know old terrigenous OC is being released; and ii) protected coastal embayments, used extensively by wildlife and Inuit, but virtually unstudied in terms of their OC cycling. Working with at least nine southern HQP and a similar number of Northerners, I will study the distributions of OC in the water column; compare winter and summer, and collect annual time series using sediment traps. We will examine the OC in sediments to inform us about recent change. Box models that constrain the rates of OC losses will immediately help put better numbers and timelines on the climate feedback associated with old terrigenous OC. Ultimately, the results will help improve how the land-ocean interface is represented in physical models, develop robust future projections, and better design monitoring plans for tracking impacts of climate change.

碳循环涉及大气、陆地和海洋，影响全球气候。有机碳（OC）是与活的或死的物质有关的部分;由植物从CO2产生，由微生物和动物转化，并通过呼吸、降解等转化为CO2。它们从陆地和海洋接收有机碳，其生产和破坏使它们成为与大气进行动态CO2交换的场所。大陆边缘还接受来自河流和海岸侵蚀的沉积物，促进有机碳的埋藏（固存）。世界上大约75%的人口生活在沿着地区，他们的生态系统服务每年价值25万亿美元。 高纬度地区正在经历快速的气候变化，包括海冰消失、河流径流改变和永久冻土融化。因此，有机碳循环将受到来源变化和有机碳在更温暖、更新鲜、更无冰和可能更有生产力的沿海沃茨中加工过程改变的影响。食物网将受到这些变化的影响，二氧化碳交换也将受到影响。最大的未知数之一是如何旧的陆源碳将有助于变化。这种碳已经被锁定在地下土壤和永久冻土中数千年，但当永久冻土融化时会释放出来，并可以在边缘地区分解为CO2，特别是当高度可降解的海洋OC发挥引发作用时。由于有非常大量的旧陆源有机碳，其退化是一个重要的潜在反馈气候变化。 这一拟议中的发现计划的总体目标是提高我们的理解的过程，决定命运的陆源OC沿着高纬度大陆边缘。其中一些过程发生在水柱中，一些发生在表层沉积物中。由于边际在空间和时间上是可变的，我们将把重点放在“热点”和“热点时刻”，进行实地研究，沿沿着i）动态，河流为主的开放式大陆架地区，我们知道旧的陆源有机碳被释放;和ii）受保护的沿海海湾，广泛使用的野生动物和因纽特人，但几乎没有研究他们的有机碳循环。与至少9个南方HQP和类似数量的北方人，我将研究OC在水柱中的分布，比较冬季和夏季，并收集年度时间序列使用沉积物陷阱。我们将检查沉积物中的有机碳，以告知我们最近的变化。限制有机碳损失率的箱形模型将立即有助于对与旧陆源有机碳相关的气候反馈提供更好的数字和时间表。最终，研究结果将有助于改善陆地-海洋界面在物理模型中的表现方式，制定强有力的未来预测，并更好地设计跟踪气候变化影响的监测计划。