冷水珊瑚骨架的形态学分析，用于评估珊瑚礁尺度破碎的硅力学模型

IF 2.8 2区生物学 Q1 MARINE & FRESHWATER BIOLOGY

Frontiers in Marine Science Pub Date : 2025-01-21 DOI:10.3389/fmars.2024.1456505

Marta Peña Fernández, Josh Williams, Janina V. Büscher, J. Murray Roberts, Sebastian J. Hennige, Uwe Wolfram

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引用次数: 0

摘要

冷水珊瑚的结构复杂性受到海洋酸化的威胁。珊瑚礁框架结构关键部分的孔隙度增加和变薄可能导致生态系统规模上的快速物理崩溃，降低其支持生物多样性的潜力。了解珊瑚礁形成珊瑚的结构-力学关系对于使用计算机力学模型作为预测工具非常重要，使我们能够确定珊瑚礁崩溃的风险和时间尺度。在这里，我们分析了冷水珊瑚物种Lophelia pertusa分支结构的形态学变化，以推进基于其骨骼结构的机械计算机模型。我们确定了五个分支间长度的临界尺寸，允许使用均质有限元模型来分析机械能力。在较小的长度尺度上，机械替代模型需要明确地考虑骨骼结构的统计形态学差异。我们发现，在L. pertusa菌落和分支之间，以及死骨和活骨片段之间，存在着很大的形态差异，这些差异受生长和对环境胁迫的适应所驱动，没有明确的分支特异性模式。未来的硅力学模型应该对这些变化进行统计模拟，作为预测冷水珊瑚礁崩溃风险的监测工具。

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Morphological analysis of cold-water coral skeletons for evaluating in silico mechanical models of reef-scale crumbling

The structural complexity of cold-water corals is threatened by ocean acidification. Increased porosity and thinning in structurally critical parts of the reef framework may lead to rapid physical collapse on an ecosystem scale, reducing their potential for biodiversity support. Understanding the structural-mechanical relationships of reef-forming corals is important to enable the use of in silico mechanical models as predictive tools that allow us to determine risk and timescales of reef collapse. Here, we analyze morphological variations of the branching architecture of the cold-water coral species Lophelia pertusa to advance mechanical in silico models based on their skeletal structure. We identified a critical size of five interbranch lengths that allows using homogenized finite element models to analyze mechanical competence. At smaller length scales, mechanical surrogate models need to explicitly account for the statistical morphological differences in the skeletal structure. We showed large morphological variations between fragments of L. pertusa colonies and branches, as well as dead and live skeletal fragments which are driven by growth and adaptation to environmental stressors, with no clear branching-specific patterns. Future in silico mechanical models should statistically model these variations to be used as monitoring tools for predicting risk of cold-water coral reefs crumbling.

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来源期刊

Frontiers in Marine Science Agricultural and Biological Sciences-Aquatic Science

CiteScore

5.10

自引率

16.20%

发文量

2443

审稿时长

14 weeks

期刊介绍： Frontiers in Marine Science publishes rigorously peer-reviewed research that advances our understanding of all aspects of the environment, biology, ecosystem functioning and human interactions with the oceans. Field Chief Editor Carlos M. Duarte at King Abdullah University of Science and Technology Thuwal is supported by an outstanding Editorial Board of international researchers. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics, policy makers and the public worldwide. With the human population predicted to reach 9 billion people by 2050, it is clear that traditional land resources will not suffice to meet the demand for food or energy, required to support high-quality livelihoods. As a result, the oceans are emerging as a source of untapped assets, with new innovative industries, such as aquaculture, marine biotechnology, marine energy and deep-sea mining growing rapidly under a new era characterized by rapid growth of a blue, ocean-based economy. The sustainability of the blue economy is closely dependent on our knowledge about how to mitigate the impacts of the multiple pressures on the ocean ecosystem associated with the increased scale and diversification of industry operations in the ocean and global human pressures on the environment. Therefore, Frontiers in Marine Science particularly welcomes the communication of research outcomes addressing ocean-based solutions for the emerging challenges, including improved forecasting and observational capacities, understanding biodiversity and ecosystem problems, locally and globally, effective management strategies to maintain ocean health, and an improved capacity to sustainably derive resources from the oceans.