基于“状态-结构”双维评估的湖南省生态安全格局构建与分区识别修复

doi:10.16258/j.cnki.1674-5906.2025.12.003

生态环境学报 ›› 2025, Vol. 34 ›› Issue (12): 1853-1865.DOI: 10.16258/j.cnki.1674-5906.2025.12.003

基于“状态-结构”双维评估的湖南省生态安全格局构建与分区识别修复

黄佳源¹(), 杨帆¹^,^*(), 邹滨², 肖雅丹³

1.中南大学建筑与艺术学院，湖南长沙 410083
2.中南大学地球科学与信息物理学院，湖南长沙 410083
3.湖南省交通规划勘察设计院有限公司，湖南长沙 410200

收稿日期:2025-04-16 出版日期:2025-12-18 发布日期:2025-12-10
通讯作者: *E-mail：yangfancsu@163.coms
作者简介:黄佳源（2000年生），女，硕士研究生，研究方向为区域生态安全、生态修复治理。E-mail: 231312033@csu.edu
基金资助:
国家自然科学基金项目(72174211);国家自然科学基金项目(51608535);中南大学中央高校基本科研业务费专项资金资助项目(2025ZZTS0418)

Identification and Restoration of Land Use Zones Based on the “State-Structure” Assessment of Ecological Security Patterns: The Case of Hunan Province

HUANG Jiayuan¹(), YANG Fan¹^,^*(), ZOU Bin², XIAO Yadan³

1. College of Architecture and Art, Central South University, Changsha 410083, P. R. China
2. College of Earth Science and Information Physics, Central South University, Changsha 410083, P. R. China
3. Hunan Provincial Institute of Transport Planning, Survey and Design, Changsha 410200, P. R. China

Received:2025-04-16 Online:2025-12-18 Published:2025-12-10

摘要/Abstract

摘要： 以生态系统服务供需状态和生态安全网络结构双维视角构建生态安全格局对于区域生态安全、生态文明建设具有重要意义。现有生态安全格局构建方法多侧重自然本底解析，难以协调服务供给能力和社会需求压力的空间匹配与网络结构的空间协同，加剧了供需错配与网络结构破碎化，制约了国土空间治理精准施策。以湖南省为例，提出“状态-结构”双维评估框架，运用InVEST模型、Z-score四象限模型、综合生态系统服务供需比（CESDR）、景观形态学分析（MSPA）和电路理论等方法，从功能状态和空间结构角度构建生态安全格局；最后运用叠加分析和交叉分类方法，构建服务于生态分区与精准修复的空间决策体系。结果表明：1）全省综合生态系统服务供需呈“四周高－中部低”的空间格局，高供-高需区占47.51%，低供-高需区占0.71%；2）识别生态源地38处，总面积3.21×10⁴ km²，跨区廊道43条，总长4.25×10³ km，划定重要生态节点7处与障碍点53处；3）结果划分出核心源地区3.27×10⁴ km²，生态保护区1.53×10⁵ km²，弹性调控区1.45×10⁵ km²，修复提升区1.55×10³ km²和城镇发展区1.98×10⁴ km²。该研究完善了生态安全格局构建的视角和技术方法，可为多地形区生态分区修复和国土空间治理提供借鉴和参考。

关键词: 生态安全格局, 生态系统服务供需, 生态安全网络, 生态分区修复, InVEST模型

Abstract:

Against the backdrop of rapid global urbanization, the imbalance between the supply and demand of ecosystem services and the disruption of network connectivity pose serious challenges to the regional ecological security. Constructing an ecological security pattern (ESP) from the dual perspectives of the supply and demand status of ecosystem services and the structural characteristics of the ecological security network has significant implications for regional ecological security and ecological civilization. Existing methods for constructing ecological security patterns primarily focus on analyzing natural baseline conditions, making it difficult to coordinate the spatial matching of service supply capacity and social demand pressure with the spatial synergy of network structures. This exacerbates supply demand mismatches and network structural fragmentation, hindering the precise implementation of policies in national land space governance. Using Hunan Province as an example, this study proposes a “state-structure” dual-dimensional assessment framework for constructing ecological security patterns in the region. State Dimension: The InVEST model was used to calculate the supply of four ecosystem services: food supply, water production, carbon sequestration, and soil conservation. A socioeconomic statistical database was used to construct an ecosystem service demand assessment model. The Ecosystem Service Supply-Demand Ratio (ESDR) was introduced to characterize the supply demand status of individual services, and the Comprehensive Ecosystem Service Supply-Demand Ratio (CESDR) was used for multi-dimensional integration. The Z-score quadrant model was applied to analyze the spatial matching characteristics of ecosystem service supply-and-demand. The structural dimension is the combination of supply and demand assessment results to select high-value areas with comprehensive supply and demand ratios as potential source areas, identifying core patches through landscape form spatial pattern analysis (MSPA), and overlaying them to create an ecological source area system. Seven factors, namely elevation, slope, land use type, NDVI vegetation index, distance to water bodies, distance to roads, and population density, were identified as resistance factors, weighted using the analytic hierarchy process (AHP), and through consistency testing and sensitivity analysis, a comprehensive resistance map was generated. Based on circuit theory methods, ecological corridors, nodes, and barrier points were identified, and the ecological safety network structure was analyzed based on the “ecological source area-ecological corridor-ecological node-ecological barrier point” framework. By integrating ecosystem service supply and demand diagnosis with ecological safety network structure identification, a spatial decision-making system was established to support ecological zoning and the precise restoration. Using a cross-classification matrix and overlay analysis methods, ecosystem service supply and demand correspond to the “state dimension,” while the ecological safety network corresponds to the “structure dimension.” With state (high, medium, or low stability) as rows and structure (high, medium, or low connectivity) as columns, a nine-cell matrix was formed, with each cell corresponding to an ecological zoning with different risk levels. By integrating ecosystem service supply demand diagnosis with ecological security network structure identification, an ecological security framework was established, along with a spatial decision-making system supporting ecological zoning and precise restoration. The results indicate: 1) Hunan Province’s ecosystem service supply exhibits a “high in southwest, low in central” spatial differentiation pattern, while ecosystem service demand shows an “evenly distributed with localized peaks” spatial pattern; the comprehensive ecosystem service supply presents a “U-shaped high supply, low in central” spatial pattern, Comprehensive ecosystem service demand exhibits a spatial pattern of “scattered high demand”; the spatial pattern of comprehensive ecosystem service supply and demand is “high around the periphery and low in the central region.” Zone I (high supply, high demand) accounts for 47.51% of the total area, encompassing 40 counties and districts with a total area of km². Zone II (low supply, high demand) accounts for 0.71%, encompassing 10 counties and districts, with a total area of km². Zone III (low supply, low demand) accounts for 20.9%, encompassing 37 counties and districts, with a total area of km². Zone IV (high supply, low demand) accounts for 30.88% of the total area, encompassing 35 counties and districts, with a total area of km². 2) 38 ecological source areas were identified, covering a total area of 3.21×10⁴ km², with 43 inter-regional corridors, including 43 important ecological corridors and 44 general ecological corridors, with a total length of 4.25×10³ km. Seven important ecological nodes and 53 obstacles were identified in this study. Large-scale ecological source areas exhibited a “west-south” winged aggregation pattern, which was highly consistent with regions where pristine ecosystems, such as the Wu ling and Nan ling Mountains in Hunan Province, were well-preserved. The resistance values on the comprehensive resistance surface ranged from 0 to 6.04 (expressed as an average), and the distribution of nodes generally aligned with the spatial pattern of ecological source points, whereas ecological obstacle points were predominantly located along the edges of ecological corridors. 3) Results: The study delineated 3.27×10⁴ km² of core source areas, 1.53×10⁵ km² of ecological protection zones, 1.45×10⁵ km² of flexible regulation zones, 1.55×10³ km² of restoration and enhancement zones, and 1.98×10⁴ km² of urban development zones. Based on ecological risk grading, five categories of zones were proposed with corresponding restoration and protection strategies: Core Source Area: Implement comprehensive intelligent monitoring and strict source protection, prohibit all development activities, and strengthen remote supervision of mountain ecological core zones; Ecological Protection Area: Enforce comprehensive ecological red line protection, establish buffer zones to block human interference, and implement statutory rigid control mechanisms; Flexible Regulation Area: Establish a flexible constraint mechanism linking development intensity with the Ecological Health Index (EHI), to guide the phasing out of low-efficiency energy use and the replacement with eco-friendly industries; Urban Development Zones: Mandate the planning of natural succession restoration land, reserve strategic blank spaces to alleviate urban pressure, and support future ecological space expansion; Restoration and Enhancement Zones: Adopt an “ecological restoration-spatial replacement- functional implantation” regulatory pathway, with restoration outcomes rigidly linked to the supply of construction land indicators. A “state-structure” dual-dimensional coupled diagnostic framework was created to address the synergistic challenges of supply demand mismatch and network fragmentation. A spatial decision support system was established, spanning assessment, identification, zoning, and restoration, to achieve precise spatial adaptation of ecological protection and restoration. This technical approach provides a scalable methodological framework for constructing ecological security patterns in diverse topographic regions, such as mountainous hills, plains, and basins, and holds significant theoretical and practical value for advancing the construction of ecological civilization.

Key words: ecological security pattern, ecosystem service supply and demand, ecological security network, ecological zone restoration, InVEST model

中图分类号:

X171.1
X32

黄佳源, 杨帆, 邹滨, 肖雅丹. 基于“状态-结构”双维评估的湖南省生态安全格局构建与分区识别修复[J]. 生态环境学报, 2025, 34(12): 1853-1865.

HUANG Jiayuan, YANG Fan, ZOU Bin, XIAO Yadan. Identification and Restoration of Land Use Zones Based on the “State-Structure” Assessment of Ecological Security Patterns: The Case of Hunan Province[J]. Ecology and Environmental Sciences, 2025, 34(12): 1853-1865.

图/表 16

图1 研究区概况图本图基于审图号为GS（2019）3266号的标准底图绘制，且未对原图边界进行任何调整，后续图示均遵循此原则

Figure 1 Overview of the study area

表1 数据来源

Table 1 Data sources

数据类型	数据来源	空间分辨率
DEM数据	地理空间数据云 http://www.gscloud.cn/	30 m
土地利用数据	资源环境科学与数据中心 https://www.resdc.cn/	1 km
土壤数据	世界土壤数据库（HWSD）的中国土壤数据集（V1.1） http://data.tpdc.ac.cn/	1 km
降雨量数据	中国气象数据网	1 km
蒸散数据	http://data.cma.cn/	500 m
NDVI数据	MODIS 数据产品 https://search.earthdata.nasa.gov/	500 m
人口数据	WorldPop 官方网站 https://www.worldpop.org/	1 km
社会经济数据	国家统计局、湖南省统计局、水资源公报	－

图2 技术框架

Figure 2 Technical framework

表2 阻力因子分级赋值及权重

Table 2 Resistance factor grading assignments and weights

阻力因子	阻力值					权重
阻力因子	1	3	5	7	9	权重
高程/m	15－200	200－400	400－700	700－1.1×10³	1.1×10³－2×10³	0.114
坡度/°	0－1.70	1.70－4.30	4.30－7.50	7.50－11.50	11.50－27.50	0.073
土地利用类型	林地	草地	耕地	水域	建设用地、未利用	0.258
植被覆盖度NDVI/km²	0.80－1.00	0.70－0.80	0.55－0.70	0.30－0.55	0－0.30	0.111
距水域距离/km²	0－0.10	0.10－0.30	0.30－0.50	0.50－0.70	0.70－1.20	0.122
距高速/铁路距离/km²	550－1600	200－550	80－200	20－80	0－20	0.105
人口密度/(person·km⁻²)	0－18.66	18.66－80.85	80.85－223.90	223.90－565.95	565.95－1.59×10³	0.217

表3 生态分区识别“状态-结构”交叉关联矩阵

Table 3 “State-structure”cross-correlation matrix for ecological zone identification

状态	结构
状态	高连通性	中连通性	低连通性
高稳定性	核心源地区	生态保护区	弹性调控区
中稳定性	生态保护区	弹性调控区	城镇发展区
低稳定性	弹性调控区	城镇发展区	修复提升区

图3 生态系统服务供给空间格局 “104 yuan?hm?2”表示“万元·公顷?1”（图4亦然）

Figure 3 Spatial pattern of ecosystem service provision

图4 生态系统服务需求空间格局

Figure 4 Spatial pattern of ecosystem service demand

图5 综合生态系统服务供给量、需求量和综合供需比

Figure 5 Total ecosystem service supply, demand, and total supply-demand ratio

图6 生态系统服务供需匹配状态和分区

Figure 6 Ecosystem service supply and demand matching status and zoning

图7 生态源地

Figure 7 Ecological sources

图8 综合阻力面

Figure 8 Integrated resistance surface

图9 生态安全网络

Figure 9 Ecological safety network

图10 生态源地辐射区

Figure 10 Ecological source radiation area

图11 生态安全格局

Figure11 Ecological security patterns

图12 生态空间分区

Figure 12 Territorial spatial subdivisions

图13 湖南省生态保护红线与生态安全格局叠加示意图

Figure 13 Schematic diagram of the overlap between Hunan Province's ecological protection red line and ecological security pattern

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基于“状态-结构”双维评估的湖南省生态安全格局构建与分区识别修复

Identification and Restoration of Land Use Zones Based on the “State-Structure” Assessment of Ecological Security Patterns: The Case of Hunan Province

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