PARTIcle Transformation and Respiration Influence on ocean Carbon Storage

颗粒转化和呼吸对海洋碳储存的影响

• 批准号: NE/Y004515/1
• 负责人: Emma Louise Cavan
• 金额: $ 40.61万
• 依托单位: Imperial College London
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2023
• 资助国家: 英国
• 起止时间: 2023 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=NE%2FY004515%2F1
• 关键词: PARTIcle; Transformation; Respiration; Influence; ocean

The ocean holds fifty times as much carbon as is in the atmosphere. Biological processes contribute to storing carbon in the ocean on climate-relevant timescales (hundreds to thousands of years). Marine phytoplankton (drifting microscopic plants) use sunlight and carbon dioxide in the upper ocean to form their bodies which are rich in carbon. When phytoplankton die they might clump together and sink into the ocean interior, or they could be eaten by zooplankton (tiny animals) which produce fecal pellets that can sink rapidly. Once this organic carbon is deeper in the water, bacteria might colonise the particles and break them down, or they could be broken apart by zooplankton feeding on them. These processes all act to reduce the amount of organic carbon reaching the deep ocean, however the deeper it goes the longer it will remain out of contact with the atmosphere. This "biological carbon pump" helps to regulate our climate, and without biology in the ocean it has been shown that atmospheric carbon dioxide levels could be nearly double what they are today.Earth system models have differing, but all fairly simple, representations of the biological carbon pump due to a lack of understanding of how the processes contributing to particle formation and respiration function. The suite of models that contribute to the Intergovernmental Panel on Climate Change reports do not agree on the magnitude or direction of change for ocean carbon storage under future climate scenarios. This means we have low confidence for our future projections of ocean carbon storage, which is further impeded by a growing discrepancy between models and observations. In this project we will examine how much carbon has been respired during the transit from the upper ocean, and in what ways. We will measure the important processes of particle fragmentation and aggregation, microbial respiration, and zooplankton vertical migration and respiration. We will do this using a process cruise and autonomous underwater vehicles. We seek to answer the question: How is organic matter transformed and respired by biotic interactions in the mesopelagic, how does that vary with depth, location and season, and what are the consequences for ocean carbon storage? The ultimate goal is to generate new detailed understanding of important processes that influence the rate and depth of interior respiration which we will scale up to provide the globally-resolved information needed to develop the next generation of biogeochemical models.

海洋中的碳含量是大气中的50倍。生物过程有助于在与气候相关的时间尺度上（数百年至数千年）将碳储存在海洋中。海洋浮游植物（漂浮的微小植物）利用海洋上层的阳光和二氧化碳形成富含碳的身体。当浮游植物死亡时，它们可能聚集在一起沉入海洋内部，或者它们可能被浮游动物（微小动物）吃掉，浮游动物产生的粪便颗粒可以迅速下沉。一旦这些有机碳深入水中，细菌可能会在这些颗粒上定居并将它们分解，或者它们可能会被以它们为食的浮游动物分解。这些过程都减少了到达深海的有机碳的数量，然而，它进入的越深，与大气接触的时间就越长。这种“生物碳泵”有助于调节我们的气候，如果海洋中没有生物，大气中的二氧化碳水平可能是今天的近两倍。由于缺乏对促进颗粒形成和呼吸功能的过程的理解，地球系统模型有不同的，但都相当简单的生物碳泵表示。为政府间气候变化专门委员会（Intergovernmental Panel on Climate Change, ipcc）报告做出贡献的一系列模型，在未来气候情景下海洋碳储量变化的幅度和方向上并不一致。这意味着我们对未来海洋碳储量预测的信心很低，而模型和观测之间越来越大的差异进一步阻碍了这一预测。在这个项目中，我们将研究在从上层海洋运输的过程中，有多少碳被呼吸，以及以什么方式呼吸。我们将测量颗粒破碎和聚集、微生物呼吸和浮游动物垂直迁移和呼吸的重要过程。我们将使用过程巡航和自主水下航行器来实现这一点。我们试图回答以下问题：有机物是如何通过中上层生物的相互作用转化和呼吸的，这是如何随着深度、位置和季节而变化的，以及对海洋碳储存的影响是什么？最终目标是对影响内部呼吸速率和深度的重要过程产生新的详细理解，我们将扩大规模，以提供开发下一代生物地球化学模型所需的全球分辨率信息。