黄河流域（内蒙古段）景观生态风险与生境质量的耦合协同关系研究

doi:10.16258/j.cnki.1674-5906.2025.12.002

生态环境学报 ›› 2025, Vol. 34 ›› Issue (12): 1841-1852.DOI: 10.16258/j.cnki.1674-5906.2025.12.002

黄河流域（内蒙古段）景观生态风险与生境质量的耦合协同关系研究

张艳¹^,²^,^*(), 张少娟¹^,², 吕韬¹^,², 贺慧汀¹^,²

1.长安大学土地工程学院，陕西西安 710054
2.陕西省土地整治重点实验室，陕西西安 710054

收稿日期:2025-04-18 出版日期:2025-12-18 发布日期:2025-12-10
通讯作者: *
作者简介:张艳（1978年生），女，副教授，博士，研究方向为土地资源管理、生态安全。E-mail: zyzhangyan@chd.edu.cn
基金资助:
国家自然科学基金项目(42371210);陕西省重大科技项目(2022ZDLSF07-05)

Research on the Coupling and Synergistic Relationship between Landscape Ecological Risk and Habitat Quality in the Yellow River Basin (Inner Mongolia Section)

ZHANG Yan¹^,²^,^*(), ZHANG Shaojuan¹^,², LÜ Tao¹^,², HE Huiting¹^,²

1. College of Land Engineering, Chang’an University, Xi’an 710054, P. R. China
2. Key Laboratory of Land Consolidation, Shaanxi Province, Xi’an 710054, P. R. China

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

摘要/Abstract

摘要：

探究黄河流域（内蒙古段）景观生态风险和生境质量的相关关系，对促进黄河流域生态文明高质量发展、提高生态系统安全具有重要意义。借助景观风险损失模型、生境质量模型等计算区域景观生态风险指数和生境质量指数，运用莫兰指数和耦合协调模型，探讨2000－2020年黄河流域（内蒙古段）的景观生态风险与生境质量的时空演变及耦合关系。结果表明，1）黄河流域（内蒙古段）的土地利用以草地和未利用为主，占比超过70%，而林地和水域面积相对较少；2000－2020年建设用地持续扩张，草地面积不断减少。2）2000－2020年（内蒙古段）的景观生态风险总体处于低水平，但风险等级整体呈上升趋势，空间上表现为鄂尔多斯市东部和巴彦淖尔市北部的低风险向高风险转移；生境质量总体较高，低值集中在以建设用地和耕地为主的中部平原区，高值集中在研究区的东部高原区，随时间的推进而演变为低生境面积不断扩大，高生境范围不断萎缩。3）景观生态风险与生境质量存在强烈的负相关关系，呈现出高值与低值相邻分布的空间集聚特征。2000－2020年黄河流域（内蒙古段）景观生态风险与生境质量的耦合程度较高，高度耦合区主要分布在河套平原，拮抗区域主要集中在西部草原区，磨合区则主要位于东部和北部的沙地及山地区域；两者的耦合协调等级以轻度失调和濒临失调为主。基于以上的研究结果，将研究区划分为三类区域进行差异化管控。研究结果可为深入理解黄河流域（内蒙古段）生态风险与生境质量的耦合协同关系以及分区管控提供参考。

关键词: 景观生态风险, 生境质量, 耦合协调度, InVEST模型, 黄河流域（内蒙古段）

Abstract:

Ecological risk refers to the adverse impact on the structure of an ecosystem in a region under external pressure and disturbance. The habitat quality of a region indicates the potential of the ecosystem to provide the necessary conditions for the survival and reproduction of species within it. Ecological risk assessment and habitat quality assessment, as two sides of the same coin of ecosystem health, are closely related to ecosystem health. Exploring the correlation between landscape ecological risk and habitat quality in the Yellow River Basin (Inner Mongolia section) is of great significance for promoting the high-quality development of ecological civilization and enhancing ecosystem security in the Basin. This study calculated the regional landscape ecological risk index and habitat quality index using landscape risk loss and habitat quality models. We used Moran’s I index and a coupling coordination model to explore the spatiotemporal evolution and coupling relationship between landscape ecological risk and habitat quality in the Yellow River Basin (Inner Mongolia section) from 2000‒2020. The results showed that: 1) Land use in the Yellow River Basin (Inner Mongolia section) is mainly grassland and unused land, accounting for more than 70%, whereas the areas of forest land and water are relatively small. The area of construction land continued to expand from 2000 to 2020, and the area of grassland was reduced during the same period. 2) The overall landscape ecological risk in the Yellow River Basin (Inner Mongolia section) was low from 2000 to 2020, with the risk level showing an upward trend. Spatially, this manifested as a shift from low risk to high risk in the eastern part of Ordos City and the northern part of Bayannur City. The overall habitat quality was relatively high, and spatially, it showed the characteristics of low values distributed in the central plain area dominated by construction and cultivated land, and high values concentrated in the plateau area in the eastern part of the study area. This was characterized by a shift from low to high risk in the central region. The habitat quality was generally high, with a spatial pattern of low quality in the center and high quality in the surrounding areas. Over time, areas with low habitat quality expanded, whereas areas with high-quality habitat shrank. 3) A strong negative correlation exists between landscape ecological risk and habitat quality, exhibiting a spatial clustering pattern of adjacent high and low values. From 2000 to 2020, the coupling degree between landscape ecological risk and habitat quality in the Yellow River Basin (Inner Mongolia section) was relatively high. The highly coupled areas were mainly distributed in the Hetao Plain, the antagonistic areas were primarily concentrated in the western grassland, and the transition areas were mainly located in the sandy and mountainous areas of the eastern and northern regions. The coupling coordination level between the two was mainly mild dysregulation and near-dysregulation, showing an upward trend. Based on the above research results, the study area was classified into three types of regions for differentiated management and control. The results provide a reference for a deeper understanding of the coupling and synergistic relationship between ecological risk and habitat quality, as well as for regionalized management and control in the Yellow River Basin (Inner Mongolia section).

Key words: landscape ecological risk, habitat quality, coupling coordination degree, InVEST model, Yellow River Basin (Inner Mongolia Section)

中图分类号:

张艳, 张少娟, 吕韬, 贺慧汀. 黄河流域（内蒙古段）景观生态风险与生境质量的耦合协同关系研究[J]. 生态环境学报, 2025, 34(12): 1841-1852.

ZHANG Yan, ZHANG Shaojuan, LÜ Tao, HE Huiting. Research on the Coupling and Synergistic Relationship between Landscape Ecological Risk and Habitat Quality in the Yellow River Basin (Inner Mongolia Section)[J]. Ecology and Environmental Sciences, 2025, 34(12): 1841-1852.

图/表 12

图1 黄河流域（内蒙古段）位置示意图审图号：GS（2024）0650号，源于国家基础地理信息中心。底图无修改

Figure 1 Location diagram of the Yellow River Basin (Inner Mongolia section)

表1 各类生境类型适宜度及对威胁因子敏感性

Table1 The suitability of each habitat type and its sensitivity to threat factors

土地利用类型	生境适宜性	相对敏感程度
土地利用类型	生境适宜性	耕地	建设用地	未利用地
耕地	0.5	0.3	0.4	0.4
林地	1	0.45	0.8	0.2
草地	0.7	0.45	0.6	0.3
水域	0.9	0.6	0.8	0.3
建设用地	0	0	0	0
未利用地	0.2	0.2	0.2	0.2

表2 威胁因子及其权重

Table 2 Threat factors and their weights

威胁因子	最大影响距离/km	权重	衰退类型
耕地	4	0.6	线性
建设用地	10	1	线性
未利用地	2	0.5	线性

图2 2000－2020年研究区土地利用图

Figure 2 Characteristics of land use spatial change in the study area from 2000 to 2020

表3 黄河流域（内蒙古段）土地利用面积及比例

Table 3 Area and proportion of land use in the Yellow River Basin (Inner Mongolia section)

土地利用类型	面积/km²			占比/%
土地利用类型	2000年	2010年	2020年	2000－2010年	2010－2020年	2000－2020年
耕地	21281.695	23793.661	20975.804	13.73	15.35	13.53
林地	6541.095	6611.267	7403.776	4.22	4.267	4.78
草地	83584.713	80371.011	81723.641	53.93	51.86	52.73
水域	3835.290	3624.804	3885.915	2.47	2.34	2.51
建设用地	3947.397	4361.625	5831.003	2.55	2.81	3.76
未利用地	35793.758	36221.454	35162.917	23.10	23.37	22.69

图3 2000－2020年土地利用转移弦图

Figure 3 Chord diagram of land use transition from 2000 to 2020

表4 2000－2020年研究区景观生态风险面积及变化量

Table 4 Landscape ecological risk area and variation in the study area from 2000 to 2020

生态风险等级	面积/km²			变化量/km²
生态风险等级	2000年	2010年	2020年	2000－2010年	2010－2020年	2000－2020年
低	28059.093	22821.737	23661.174	−5237.357	839.437	−4397.920
较低	48665.446	39099.514	38986.373	−9565.932	−113.142	−9679.073
中等	31759.915	39004.622	39895.155	7244.706	890.533	8135.239
较高	24690.396	31165.011	29894.906	6474.614	−1270.105	5204.509
高	21808.864	22892.833	22546.109	1083.969	−346.724	737.245

图4 景观生态风险分布图

Figure 4 Landscape ecological risk distribution

图5 黄河流域（内蒙古段）生境质量时空分布图

Figure 5 The spatio-temporal distribution map of habitat quality in the Yellow River Basin (Inner Mongolia section)

图6 2000－2020年研究区LISA聚类图

Figure 6 LISA cluster map of the study area from 2000 to 2020

图7 景观生态风险与生境质量的耦合关系

Figure 7 The coupling relationship between landscape ecological risk and habitat quality

图8 景观生态风险与生境质量耦合协调类型

Figure 8 The coupling coordination type between landscape ecological risk and habitat quality

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黄河流域（内蒙古段）景观生态风险与生境质量的耦合协同关系研究

Research on the Coupling and Synergistic Relationship between Landscape Ecological Risk and Habitat Quality in the Yellow River Basin (Inner Mongolia Section)

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