水网城市湿地生态网络韧性评价——以苏州中心城区为例

doi:10.11707/j.1001-7488.LYKX20240260

Abstract

Abstract:

Objective: Extract the spatial elements of various types of wetlands in in Suzhou central urban area, construct the wetland ecological network, quantitatively evaluate the resilience level of the wetland ecological network, and provide a scientific basis for the resilience measurement and spatial conservation planning of wetland ecological networks in water network city. Method: Taking the central urban area of Suzhou as an example, a water network urban wetland ecological network is constructed based on the “MSPA-Conefor-MCR-GM” model. The complex network analysis method is used to select indicators that can reflect the resilience characteristics and levels of the wetland ecological network. The resilience level of the wetland ecological network is quantitatively measured from three dimensions: structure, function, and composition, and key wetland patches and ecological corridors in the region are identified. Result: 1) 19 ecological source areas, 171 potential ecological corridors and 28 important ecological corridors were extracted from the central urban area of Suzhou, and 137 ecological nodes were identified, forming a typical network like multi cluster and multi node structural feature. Among them, ecological source areas exhibit spatial distribution characteristics of “multi center, multi cluster”, potential ecological corridors exhibit spatial distribution characteristics of“northeast-central dense network ,other regions exhibit minimal or negligible”, important ecological corridors exhibit spatial distribution characteristics of“northeast-southwest orientation, partially grid-like”, and ecological nodes form spatial distribution characteristics of “overall dispersion, local compactness”. 2) In terms of structural resilience, the average clustering coefficient of the wetland ecological network in the central urban area is 0.04, the average degree of the network is 3.12, and the scale-free characteristics are obvious. The aggregation is weak, the connectivity is average, and the structural resilience is insufficient. 3) In terms of functional resilience, the average path length, network efficiency value, average node structure hole value, and average k-core index value are 5.47, 0.19, 0.41, and 2.02, respectively. The average number of independent paths between nodes is still acceptable, and the network diversity is high. However, due to the impact of urban construction, the corridors between patches are relatively long, with insufficient transmission and stability, and weak collaboration. 4) In terms of component resilience, the node centrality range is 0?2 837.17, with an average value of 365.17, and the edge centrality range is 1?2 618.76, with an average value of 1 469.43. There are significant differences in the importance of plaques and corridors, with strong spatial heterogeneity and significant differences in component resilience levels. Conclusion: The resilience level of the wetland ecological network in the central urban area of Suzhou is generally average, with different characteristics and levels of structural resilience, functional resilience, and component resilience. The research results can serve as a baseline reference for wetland ecological protection and management in this area.

Key words: wetlands, wetland ecological network, complex network analysis method, resilience evaluation, water network city

CLC Number:

Ying Zhu,Xinyu Zhou,Yuqing Feng,Hui Wang,Xin Li. Resilience Evaluation of Wetland Ecological Network in Water Network City: a Case Study of Suzhou Central Urban Area[J]. Scientia Silvae Sinicae, 2025, 61(2): 62-73.

Figures/Tables 12

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Table 1

Table 2

Resilience evaluation indicators for wetland ecological networks"

评价维度 Evaluation dimension	反映特征 Reflective features	指标 Indicator	指标内涵 Indicator connotation	参考文献 References
结构韧性 Structural resilience	聚集性Aggregation	平均聚类系数 Average clustering coefficient	反映网络整体的聚集程度，且平均聚类系数越大，节点间联系越紧密 Reflecting the overall clustering degree of the network, and the larger the average clustering coefficient, the closer the connections between nodes	Watts et al.，1998
结构韧性 Structural resilience	连通性Connectivity	平均度 Average degree	反映网络的整体连通性，平均度越高，意味着网络的整体连通性越强 Reflecting the overall connectivity of the network, the higher the average degree, the stronger the overall connectivity of the network	Barabási et al.，1999
功能韧性Functional resilience	多样性 Diversity	平均路径长度 Average path length	反映节点之间存在多种连接路径，以确保廊道有断裂危险时，能够保持两个生态源之间的连接，值越大，多样性越强 Reflecting the existence of multiple connection paths between nodes to ensure that when there is a risk of breakage in the corridor, the connection between two ecological sources can be maintained. The larger the value, the stronger the diversity	Watts et al.，1998
	传递性Transmissibility	网络效率 Network efficiency	反映生态网络物质能量流动的运行效率，值越大，生态流的迁移效率越高 Reflecting the operational efficiency of material and energy flow in ecological networks, the larger the value, the higher the migration efficiency of ecological flow	Latora et al.，2001
	协作性Collaboration	节点结构孔 Node structure hole	表示节点对网络中其他节点的依赖程度，反映了节点的区域协作能力，值越小，对周围节点的功能约束越小，协作性越强 Indicates the degree of dependence of a node on other nodes in the network, reflecting the node’s regional cooperation ability. The smaller the value, the less functional constraints it has on surrounding nodes, and the stronger the cooperation	Burt，1992
	稳定性 Stability	k核指数 K-core index	反映生态系统在遇到干扰时保持稳定和持续运行的能力，值越高且比例越大，网络功能越稳定 Reflecting the ability of ecosystems to maintain stability and continuous operation in the face of disturbances, the higher the value and the larger the proportion, the more stable the network function	Seidman，1983
组分韧性 Component resilience	斑块重要性Importance of plaques	节点介数中心性 Node betweenness centrality	表示网络中任何两个节点间的最短路径经过某个节点的总次数，代表生态网络中一个斑块在能量流动和信息传递中的重要性 The total number of times the shortest path between any two nodes in the network passes through a node, representing the importance of a patch in energy flow and information transmission in the ecological network	Freeman ，1977
组分韧性 Component resilience	廊道重要性Importance of corridor	边介数中心性 Edge betweenness centrality	反映网络中节点和廊道的重要性，值越大，在应对人类活动干扰和栖息地退化方面的韧性越强，网络也越稳定 Reflecting the importance of nodes and corridors in the network, the larger the value, the stronger the resilience in dealing with human activity interference and habitat degradation, and the more stable the network	Girvan et al.，2002

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阻力因子 Resistance factor	阻力值 Resistance value					权重Weight
阻力因子 Resistance factor	1	2	3	4	5	权重Weight
土地利用类型 Land use type	湿地 Wetlands	林地、草地 Forest， grassland	耕地 Cultivated land	未利用地 Unutilized land	建设用地 Construction land	0.25
植被覆盖度 Vegetation coverage	0.80~1.00	0.60~0.80	0.50~0.60	0.20~0.50	0~0.20	0.15
水网密度 Water network density/(km·km^–2)	27.90~ 54.94	20.33~27.90	13.41~20.33	5.84~13.41	0~5.84	0.24
河道密度 Channel density/(km·km^–2)	1.85~3.65	1.26~1.85	0.77~1.26	0.30~0.77	0~0.30	0.20
路网密度 Road network density/(km·km^–2)	0~4.08	4.08~7.95	7.95~11.93	11.93~16.95	16.95~26.68	0.06
距建设用地距离 Distance from construction land/m	>2 500	1 500~2 500	1 000~1 500	500~1 000	<500	0.10

[1]	Zhang Manyin;Cui Lijuan;Li Wei;Wang Yifei;Zhao Xinsheng;Li Shengnan;Gao Shiwu;Zhang Yan. Management Assessment of Beijing Cuihu Wetland Park [J]. Scientia Silvae Sinicae, 2011, 47(5): 153-156.
[2]	Yuan Jun;;Lü Xianguo. Development and Application of A Dual-Grade Fuzzy Pattern Recognition Model on Functional Assessment of Wetlands [J]. Scientia Silvae Sinicae, 2005, 41(4): 1-6.

Resilience Evaluation of Wetland Ecological Network in Water Network City: a Case Study of Suzhou Central Urban Area

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