黄河三角洲高效生态经济区生态网络构建与评价

doi:10.13287/j.1001-9332.202511.027

摘要/Abstract

摘要： 在经济发展和城镇扩张的背景下,生境斑块破碎化有加剧趋势,合理构建生态网络可以连接区域破碎的生境斑块、改善景观连通性、提升生态系统服务能力、促进生态系统健康发展。本研究采用形态学空间格局分析和景观连通性分析方法筛选生态源地,借助最小成本阻力模型叠加多因子构建生态阻力面,结合电路理论提取生态廊道、夹点及障碍点,按照“源地-廊道-节点”的范式构建了黄河三角洲高效生态经济区的生态网络,并对生态网络进行了结构和韧性分析。结果表明: 研究区共识别出41处生态源地,总面积为2994.45 km²。提取出21条一级生态廊道、26条二级生态廊道及18条三级生态廊道,长度共计1655.42 km,平均长度25.46 km。识别出生态夹点127处,面积共32.92 km²,生态障碍点20处,分别对应需重点开展生态保护和生态修复工作的区域。研究区生态网络闭合度指数为0.74,连接度指数为2.32,连通度指数为0.83,网络结构比较完善。生态网络连通稳健性和脆弱稳健性的初始值分别为0.98和0.42,边失效比率45%、节点失效比率20%是该区域网络功能稳定的临界值。本研究结果对黄河三角洲高效生态经济区景观破碎化治理、生物栖息地保护、生态安全格局构建具有重要的指导价值,并为生态网络评价研究提供了思路和参考。

关键词: 生态网络, 黄河三角洲高效生态经济区, 形态学空间格局分析, 电路理论, 稳健性, 韧性

Abstract: The fragmentation of habitat patches is rising due to economic development and urban expansion. The systematic design of an ecological network can link fragmented habitat patches, improve landscape connectivity, augment ecosystem service capabilities, and foster the robust development of the ecosystem. We employed the methods of morphological spatial pattern analysis and landscape connectivity analysis to identify ecological source areas, and utilized the minimal cost resistance model through the superimposition of multiple factors to construct the ecological resistance surface. Combining circuit theory to extract ecological corridors, grips, and obstacle points, we constructed the ecological network of the Yellow River Delta Efficient Ecological Economic Zone by using the “source-corridor-node” paradigm and analyzed the structure and resilience of this network. We identified 41 ecolo-gical sources regions, with a total area of 2994.45 km². We extracted 21 first-level ecological corridors, 26 second-level ecological corridors, and 18 third-level ecological corridors, with a total length of 1655.42 km and an average length of 25.46 km. We identified 127 ecological pinch points with a total of 32.92 km² and 20 ecological obstacles, corresponding to regions that required key ecological conservation and restoration work. The ecological network closure index was 0.74, the connectivity index was 2.32, and the connectivity index was 0.83, indicating a relatively comprehensive ecological network structure. The initial values of the connectivity robustness and vulnerability robustness of the ecological network were 0.98 and 0.42, respectively. The critical values for the stability of the ecological network function were an edge failure ratio of 45% and a node failure ratio of 20%. Generally, our findings have significant reference and guiding value for the landscape fragmentation management, biological habitat protection, development of ecological security, and ecdogical network evaluation in the Yellow River Delta Efficient Ecological Economic Zone.

Key words: ecological network, Yellow River Delta Efficient Ecological Economic Zone, morphological spatial pattern analysis, circuit theory, robustness, resilience

朱亚杰, 栗云召, 刘言智, 唐紫微, 闫畅, 白云逸, 于君宝, 杨继松. 黄河三角洲高效生态经济区生态网络构建与评价[J]. 应用生态学报, 2025, 36(11): 3457-3466.

ZHU Yajie, LI Yunzhao, LIU Yanzhi, TANG Ziwei, YAN Chang, BAI Yunyi, YU Junbao, YANG Jisong. Construction and evaluation of ecological network in the Yellow River Delta High-efficiency Ecological Economic Zone[J]. Chinese Journal of Applied Ecology, 2025, 36(11): 3457-3466.

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