Seabed Mining And Resilience To EXperimental impact

海底采矿和实验影响的恢复能力

• 批准号: NE/T00293X/1
• 负责人: Kerry Howell
• 金额: $ 14.29万
• 依托单位: Plymouth University
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2021
• 资助国家: 英国
• 起止时间: 2021 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=NE%2FT00293X%2F1
• 关键词: Seabed; Mining; Resilience; EXperimental; impact

Over a 6 million square km region of the central Pacific ocean, at abyssal depths of almost five thousand metres, lies a vast mineral resource in the form of small potato-sized deposits called polymetallic nodules. They are highly-enriched in metals of importance for industry, including the development of new sustainable technologies. Although the region lies in international waters, countries have now signed 16 exploration contracts with a UN-organised international regulator and the United Kingdom is sponsor to two of these, covering an area more than the size of England. It is a requirement of both the regulator and the sponsoring state to ensure that serious harm is avoided to the marine ecosystem in this region - a hitherto untouched deep-sea wilderness. Developing a sustainable approach to polymetallic nodule mining is a challenge as the nature and importance of the Pacific abyssal ecosystem is largely unknown, as are the capacity of the ecosystem to cope with and recover from mining impacts. Our project aims to provide the critical scientific understanding and evidence-base to reduce the risks of this industrial development, taking advantage of two new and unique opportunities to solve these problems in a single programme. Firstly, the UK contractor that holds the UK-sponsored exploration contract (UK Seabed Resources) is planning a mining test in 2023, which will allow us to test the immediate impacts of a seabed mining vehicle for the first time. Secondly, as a partner in the first full-scale mining test done in 1979, they have been able to release new data on the location and results of a 40-year old large-scale mining operation. Our project team have secured access to data and test plans, to allow detailed experimental evaluation of impact and recovery from realistic mining disturbance on a decadal scale of vital relevance to understanding the long-term sustainability of deep-sea mining.The project aims to better understand the ecosystem in the Pacific abyss and how the different components interact and interconnect. We will start by assessing the water and its dynamic flows over time and space. This complex physical environment will be monitored for a year to capture its variabilities, particularly "storm events" near the seabed. We will use this to make predictions about where the sediment plume generated by mining will be transported and settle back to the seafloor. We then assess the linkages between the water, sediment surface and sub sediments, evaluating the natural cycling of nutrients and metals that is important to maintain ecosystem health. The impacts of mining and recovery of these processes will be assessed. Mining will lead to changes in the structure of the seabed, its shape and the physical nature of the sediments, which will be mapped and linked to biological patterns. The biological processes that lead to these patterns will be assessed by detailing the life histories and reproduction of the organisms present and their connectivity between areas near and far, and then determining their role in maintaining structured communities of life, a high biodiversity and a functioning food web. We will then evaluate the functions in the ecosystem that these organisms provide, which help maintain a healthy ecosystem. The impact of mining and recovery of all these patterns and processes will be determined using our experimental areas to assess the biological and functional consequences of disturbance in the deep sea. These changes are likely complex, so a range of mathematical models will be used to better understand and predict the consequences of mining activities at larger time and space scales. Such predictive power, along with the evidence from the scientific assessment, will provide information that is critical for understanding and reducing the environmental risk of future mining activities.

太平洋中部超过600万平方公里的区域，在近5000米的深海深处，蕴藏着巨大的矿产资源，其形式是马铃薯大小的小矿床，称为多金属结核。它们富含对工业至关重要的金属，包括开发新的可持续技术。虽然该地区位于国际水域，但各国目前已与联合国组织的国际监管机构签署了16份勘探合同，其中英国是其中两份的赞助商，覆盖面积比英格兰还大。监管机构和赞助国都要求确保避免对该地区的海洋生态系统造成严重损害——这是一片迄今为止未被触及的深海荒野。制定多金属结核采矿的可持续办法是一项挑战，因为太平洋深海生态系统的性质和重要性在很大程度上是未知的，生态系统应对采矿影响并从中恢复的能力也是未知的。我们的项目旨在提供关键的科学理解和证据基础，以减少这种工业发展的风险，利用两个新的和独特的机会在一个项目中解决这些问题。首先，持有英国赞助勘探合同的英国承包商（英国海底资源公司）计划在2023年进行采矿测试，这将使我们能够首次测试海底采矿车的直接影响。第二，作为1979年进行的第一次全面采矿试验的合作伙伴，它们已经能够公布关于40年历史的大规模采矿作业的地点和结果的新数据。我们的项目团队已经获得了数据和测试计划，以便对实际采矿干扰的影响和恢复进行详细的实验评估，这与了解深海采矿的长期可持续性至关重要。该项目旨在更好地了解太平洋深渊的生态系统，以及不同组成部分如何相互作用和相互联系。我们将从评估水及其随时间和空间的动态流动开始。这一复杂的物理环境将被监测一年，以捕捉其变化，特别是海底附近的“风暴事件”。我们将用它来预测采矿产生的沉积物将在哪里被运输并沉降到海底。然后，我们评估了水、沉积物表面和下层沉积物之间的联系，评估了对维持生态系统健康至关重要的营养物质和金属的自然循环。将评估这些过程的采矿和回收的影响。采矿将导致海底的结构、形状和沉积物的物理性质发生变化，这些变化将被绘制出来并与生物形态联系起来。导致这些模式的生物过程将通过详细描述生物的生活史和繁殖以及它们在远近地区之间的连通性来评估，然后确定它们在维持结构化的生命群落、高度生物多样性和功能良好的食物网方面的作用。然后，我们将评估这些生物在生态系统中提供的功能，这些功能有助于维持健康的生态系统。所有这些模式和过程的开采和恢复的影响将通过我们的实验区来评估深海扰动的生物和功能后果来确定。这些变化可能很复杂，因此将使用一系列数学模型来更好地了解和预测在更大的时间和空间尺度上采矿活动的后果。这种预测能力，连同科学评估的证据，将提供对了解和减少未来采矿活动的环境风险至关重要的信息。