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全球范围内拆除人造建筑对海洋生态系统影响的证据:一项系统综述

Evidence for the effects of decommissioning man-made structures on marine ecosystems globally: a systematic map.

作者信息

Lemasson Anaëlle J, Somerfield Paul J, Schratzberger Michaela, McNeill Caroline Louise, Nunes Joana, Pascoe Christine, Watson Stephen C L, Thompson Murray S A, Couce Elena, Knights Antony M

机构信息

School of Biological and Marine Sciences, University of Plymouth, Drake Circus, Plymouth, PL4 8AA, UK.

PML -Plymouth Marine Laboratory, Prospect Place, The Hoe, Plymouth, PL1 3DH, UK.

出版信息

Environ Evid. 2022 Nov 1;11(1):35. doi: 10.1186/s13750-022-00285-9.

DOI:10.1186/s13750-022-00285-9
PMID:39294784
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11378805/
Abstract

BACKGROUND

Many marine man-made structures (MMS), such as oil and gas platforms or offshore wind turbines, are nearing their 'end-of-life' and require decommissioning. Limited understanding of MMS decommissioning effects currently restricts the consideration of alternative management possibilities, often leaving complete removal as the only option in certain parts of the world. This evidence-base describes the ecosystem effects of marine MMS whilst in place and following cessation of operations, with a view to informing decision-making related to their potential decommissioning.

METHOD

The protocol used to create this map was published a priori. Systematic searches of published, literature in English were conducted using three bibliographic databases, ten specialist organisational websites or repositories, and one search engine, up to early 2021. A total of 15,697 unique articles were identified as potentially relevant to our research questions, of which 2,230 were screened at the full-text level. Of that subset, 860 articles met all pre-defined eligibility criteria. A further 119 articles were identified through "snowballing" of references from literature reviews. The final database consists of 979 articles. For each article included, metadata were extracted for key variables of interest and coded into a database.

REVIEW FINDINGS

The vast majority of eligible articles related to the presence of MMS (96.2%), while just 5.8% considered decommissioning. Overall, articles mainly considered artificial reefs (51.5% of all articles) but increasingly oil and gas (22%), shipwrecks (15.1%) and offshore wind (13.1%). Studies were distributed globally, but the majority focused on the United States, single countries within Europe, Australia, Brazil, China, and Israel; 25 studies spanned multiple countries. Consequently, the bulk of the studies focused on the North Atlantic (incl. Gulf of Mexico, North Sea, and Mediterranean Sea) and North Pacific Oceans. A further 12 studies had a global scope. Studies in majority reported on fish (53%) and invertebrates (41%), and were disproportionately focused on biological (81%) and ecological (48%) impacts. Physico-chemical (13%), habitat (7%), socio-cultural (7%), economic (4%) and functional (8%) outcomes have received less attention. The number of decommissioning studies has been increasing since ca. 2012 but remains noticeably low. Studies mostly focus on oil and gas infrastructures in the USA (Gulf of Mexico) and Northern Europe (North Sea), covering 9 different decommissioning options.

CONCLUSIONS

This systematic map, the first of its kind, reveals a substantial body of peer-reviewed evidence relating to the presence of MMS in the sea and their impacts, but with considerable bias toward biological and ecological outcomes over abiotic and socio-economic outcomes. The map reveals extremely limited direct evidence of decommissioning effects, likely driven at least in part by international policy preventing consideration of a range of decommissioning options beyond complete removal. Despite evidence of MMS impacts continuing to grow exponentially since the early 1970s, this map reveals key gaps in evidence to support best practice in developing decommissioning options that consider environmental, social and economic effects. Relevant evidence is required to generate greater understanding in those areas and ensure decommissioning options deliver optimal ecosystem outcomes.

摘要

背景

许多海洋人造结构(MMS),如石油和天然气平台或海上风力涡轮机,正接近其“使用寿命结束”阶段,需要退役。目前对MMS退役影响的了解有限,这限制了对替代管理可能性的考虑,在世界某些地区,通常使得完全拆除成为唯一选择。本证据库描述了海洋MMS在运行期间和停止运行后的生态系统影响,旨在为与其潜在退役相关的决策提供信息。

方法

用于创建此地图的方案已事先公布。截至2021年初,使用三个书目数据库、十个专业组织网站或存储库以及一个搜索引擎,对已发表的英文文献进行了系统检索。共识别出15697篇与我们的研究问题潜在相关的独特文章,其中2230篇在全文层面进行了筛选。在该子集中,860篇文章符合所有预先定义的纳入标准。通过对文献综述参考文献的“滚雪球”式搜索又识别出119篇文章。最终数据库由979篇文章组成。对于每篇纳入的文章,提取了感兴趣的关键变量的元数据并编码到数据库中。

综述结果

绝大多数符合条件的文章与MMS的存在相关(96.2%),而只有5.8%考虑了退役。总体而言,文章主要关注人工鱼礁(占所有文章的51.5%),但石油和天然气(22%)、沉船(15.1%)和海上风电(13.1%)的关注度也在增加。研究分布在全球,但大多数集中在美国、欧洲的单个国家、澳大利亚、巴西、中国和以色列;25项研究跨越多个国家。因此,大部分研究集中在北大西洋(包括墨西哥湾、北海和地中海)和北太平洋。另有12项研究具有全球范围。大多数研究报告了鱼类(53%)和无脊椎动物(41%),并且不成比例地侧重于生物(81%)和生态(48%)影响。物理化学(13%)、栖息地(7%)、社会文化(7%)、经济(4%)和功能(8%)方面的结果受到的关注较少。自2012年左右以来,退役研究的数量一直在增加,但仍然明显较少。研究大多集中在美国(墨西哥湾)和北欧(北海)的石油和天然气基础设施,涵盖9种不同的退役选项。

结论

这张同类中的首张系统地图揭示了大量关于海洋中MMS的存在及其影响的同行评审证据,但在非生物和社会经济结果方面,对生物和生态结果存在相当大的偏向。该地图显示退役影响的直接证据极其有限,这可能至少部分是由于国际政策阻止考虑除完全拆除之外的一系列退役选项。尽管自20世纪70年代初以来,有证据表明MMS的影响呈指数级增长,但该地图揭示了在支持制定考虑环境、社会和经济影响的退役选项的最佳实践方面,证据存在关键差距。需要相关证据来加深对这些领域的理解,并确保退役选项能带来最佳的生态系统结果。

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