Reasonable fragment size and transplant density can effectively improve coral restoration efficiency

IF 4.1 2区环境科学与生态学 Q1 ECOLOGY

Ecological Engineering Pub Date : 2025-09-17 DOI:10.1016/j.ecoleng.2025.107805

He Zhao , Junling Zhang , Xiangbo Liu , Wentao Zhu , Baruch Rinkevich , Shai Shafir , Yijing Di , Aimin Wang , Xiubao Li

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引用次数: 0

Abstract

Coral restoration technologies are vital for rehabilitating degraded coral reefs, with the gardening approach used as the main global method. However, the success of these efforts depends on restoration-related factors, including coral species selection, fragment size, and transplant density. Here we monitored for over one year period fragments of opportunity from four coral species, Acropora hyacinthus, Acropora microphthalma, Porites cylindrica, and Montipora digitata, that were transplanted on “Framed Reef Modules” located at Wuzhizhou Island, Hainan, China. The fragments were divided into three groups, representing three fragment sizes and two spacing regimens, in four replicates: Group 1 (6 cm size; 16 colonies; spacing 30 cm), Group 2 (3 cm; 32 colonies; spacing 15 cm), Group 3 (6 cm; 32 colonies; spacing 15 cm). Coral survival, growth rates, and physiological parameters were continuously monitored. In A. hyacinthus and P. cylindrica, large fragment size and lower transplant density significantly enhanced growth and survival rates. Under high-density transplant condition, smaller A. microphthalma fragments exhibited higher survival rates. Lower density transplantation significantly improved the survival rate of M. digitata, while its growth rate was not affected by either fragment size or transplant density. Environmental factors, such as seawater temperature, turbidity, and nutrient concentrations, significantly affected coral growth during the 90 to 180 days post-transplantation, when increased environmental stress inhibited coral growth rates. This study adds to our understanding of the selection of fragment size and spacing in direct active transplantation of corals of opportunity.

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合理的碎片大小和移植密度可有效提高珊瑚恢复效率

珊瑚恢复技术对于恢复退化的珊瑚礁至关重要，园艺方法是全球使用的主要方法。然而，这些努力的成功取决于与恢复相关的因素，包括珊瑚物种选择、碎片大小和移植密度。在海南蜈支洲岛的“框架礁模块”上，我们对四种珊瑚（风信子Acropora hyacinthus， Acropora microphthalma, Porites ica, Montipora digitata）移植的机会片段进行了一年多的监测。片段分为3组，分别代表3种片段大小和2种间隔方案，共4个重复：1组（6 cm大小，16个菌落，间隔30 cm）， 2组（3 cm， 32个菌落，间隔15 cm）， 3组（6 cm， 32个菌落，间隔15 cm）。连续监测珊瑚的存活率、生长率和生理参数。在风信子和白茅中，较大的断片尺寸和较低的移栽密度显著提高了其生长和成活率。高密度移植条件下，小眼盲蝽碎片越小，存活率越高。低密度移植显著提高了金针桃的成活率，而其生长速率不受碎片大小和移植密度的影响。环境因素，如海水温度、浊度和营养物质浓度，在移植后90至180天内显著影响珊瑚的生长，此时环境胁迫增加抑制了珊瑚的生长速度。本研究增加了我们对珊瑚直接主动移植中碎片大小和间距选择的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ecological Engineering 环境科学-工程：环境

CiteScore

8.00

自引率

5.30%

发文量

293

审稿时长

57 days

期刊介绍： Ecological engineering has been defined as the design of ecosystems for the mutual benefit of humans and nature. The journal is meant for ecologists who, because of their research interests or occupation, are involved in designing, monitoring, or restoring ecosystems, and can serve as a bridge between ecologists and engineers. Specific topics covered in the journal include: habitat reconstruction; ecotechnology; synthetic ecology; bioengineering; restoration ecology; ecology conservation; ecosystem rehabilitation; stream and river restoration; reclamation ecology; non-renewable resource conservation. Descriptions of specific applications of ecological engineering are acceptable only when situated within context of adding novelty to current research and emphasizing ecosystem restoration. We do not accept purely descriptive reports on ecosystem structures (such as vegetation surveys), purely physical assessment of materials that can be used for ecological restoration, small-model studies carried out in the laboratory or greenhouse with artificial (waste)water or crop studies, or case studies on conventional wastewater treatment and eutrophication that do not offer an ecosystem restoration approach within the paper.