How to Optimize High-Value GEP Areas to Identify Key Areas for Protection and Restoration: The Integration of Ecology and Complex Networks

Remote. Sens. Pub Date : 2023-07-06 DOI:10.3390/rs15133420

Luying Wang, Siyuan Wang, Xiaofei Liang, Xuebing Jiang, Jiping Wang, Chuang Li, Shihui Chang, Y. You, Kai Su

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引用次数: 2

Abstract

Identifying and protecting key sites of ecological assets and improving spatial connectivity and accessibility are important measures taken to protect ecological diversity. This study takes Guangxi as the research area. Based on the gross ecosystem product (GEP), the ecological source is identified, and the initial ecological network (EN) is constructed by identifying the ecological corridor with the minimum cumulative resistance model. The internal defects of the initial ecological network are extracted using the circuit theory, the priority areas for restoration and protection with clear spatial positions are determined according to the complex network analysis, and the network’s performance before and after optimization is comprehensively evaluated. The results show that 456 initial ecological sources and 1219 ecological corridors have been identified, forming the initial ecological network of Guangxi. Based on the circuit theory, 168 ecological barriers, 83 ecological pinch points, and 71 ecological stepping stones were extracted for network optimization. After optimizing the ecological network, there are 778 ecological sources with a total area of 73,950.56 km2 and 2078 ecological corridors with a total length of 23,922.07 km. The GEP of the optimized structure is 13.33% higher than that of the non-optimized structure. The priority areas for protection are distributed in a large area, and the attached GEP reaches USD 118 billion, accounting for 72% of the total GEP attached to the optimized ecological source area. The priority areas for restoration are scattered in small patches, with a GEP of USD 19.27 billion. The robustness and connectivity of the optimized ecological network have been improved obviously. This study attempts to identify key sites of ecological assets and the priority regions for restoration and conservation using genuine geographical location and reference materials for regional ecological network optimization and implementation.

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如何优化高价值GEP区域以确定重点保护和修复区域:生态与复杂网络的整合

确定和保护重点生态资产场所，提高空间连通性和可达性，是保护生态多样性的重要措施。本研究以广西为研究区域。以生态系统生产总值(GEP)为基础，通过最小累积阻力模型识别生态廊道，构建初始生态网络(EN)。利用电路理论提取初始生态网络的内部缺陷，根据复杂网络分析确定空间位置明确的优先修复保护区域，综合评价优化前后的网络性能。结果表明:广西已确定初始生态源456个，生态廊道1219个，形成了广西初始生态网络。基于电路理论，提取了168个生态屏障、83个生态捏点和71个生态垫脚石进行网络优化。优化后的生态网络有生态资源778个，总面积73950.56 km2;生态廊道2078个，总长23922.07 km。优化后结构的GEP比未优化结构高13.33%。重点保护区域分布较广，生态资源附加价值达1180亿美元，占优化生态源区域生态资源附加价值的72%。优先恢复区域分散在小块区域，全球经济目标为192.7亿美元。优化后的生态网络鲁棒性和连通性明显提高。本研究试图利用真实的地理位置和参考资料，确定生态资产的重点地点和修复保护的优先区域，为区域生态网络的优化和实施提供参考。

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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Remote. Sens.

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