楚雄彝族自治州景观生态风险评价和生态安全格局构建

doi:10.13287/j.1001-9332.202511.026

摘要/Abstract

摘要： 探讨金沙江流域干热河谷区域的景观生态风险和生态保护修复对策,对进一步推动长江经济带高质量发展具有重要意义。本研究以楚雄彝族自治州为研究区,通过InVEST和Zonation模型评价景观生态风险、判断其生态本底状况,并结合干热河谷区域生态特点构建生态安全格局以指导生态修复策略的制定,从而保障区域生态安全。结果表明: 研究区生态风险呈现斑块状镶嵌、局部集聚的格局,高风险斑块集中在干热河谷区和城市扩展区,低风险区主要在山地林区。面积阈值设定为5 km²,得到生态源地154个,占全州总面积的19.5%,主要分布在林地面积较大的哀牢山、百草岭和乌蒙山。生态廊道241条,总长度2779.49 km,呈四周短、中部长的分布状况;生态夹点173个,总面积57.87 km²,最大夹点面积为13.44 km²;生态障碍点101个,总面积172.14 km²,主要分布在铁路、高速公路等人类活动影响较大的区域;以生态源地为基础,根据生态廊道的连通方向并结合生态阻力面进行分区,构建了“三区、四带、多点”的生态安全格局,并提出对应的生态修复策略。本研究结果可为楚雄州生态保护和可持续发展提供理论支持,并能为干热河谷地区生态保护修复提供参考价值。

关键词: 景观生态风险, 生态安全格局, 楚雄彝族自治州, 生态修复策略

Abstract: Exploring the landscape ecological risk and ecological protection and restoration strategies in the dry-hot valley region of the Jinsha River Basin is of great significance for promoting the high-quality development of the Yangtze River Economic Belt. With Chuxiong Yi Autonomous Prefecture as the research area, we evaluated landscape ecological risk and determined its ecological background using the InVEST and Zonation models, and further constructed the ecological security pattern by integrating the ecological characteristics of dry-hot valley regions to guide the formulation of ecological restoration strategies, thereby ensuring regional ecological security. The results showed that there is a patchy and locally aggregated pattern of ecological risks , with high-risk patches being concentrated in dry-hot valley areas and urban expansion zones and low-risk areas being mainly found in mountainous forest regions. With an area threshold of 5 km², we identified 154 ecological sources, accounting for 19.5% of the total area of the prefecture, mainly distributed in Ailao Mountain, Baicao Ridge, and Wumeng Mountain with large forest area. We extracted a total of 241 ecological corridors with a combined length of 2779.49 km, which showed a distribution pattern of shorter corridors around the periphery and medium-to-longer corridors in the interior. There were 173 ecological pinch points with a total area of 57.87 km², and the area of the largest pinch point was 13.44 km². The number of ecological barriers was 101 with a total area of 172.14 km², mainly distributed in areas heavily affected by human activities such as railways and expressways. Based on ecological sources, combined with the connectivity direction of ecological corridors and the resistance surface, we constructed an ecological security pattern of “three zones, four belts, and multiple points”, and proposed corresponding ecological restoration strategies. This study would provide theoretical support for ecological protection and sustainable development in Chuxiong Yi Autonomous Prefecture and offer reference value for ecological protection and restoration in dry-hot valley regions.

Key words: landscape ecological risk, ecological security pattern, Chuxiong Yi Autonomous Prefecture, ecological restoration strategy

陈昆仑, 林如梦, 陈恁宇, 何丽娜, 何清俊. 楚雄彝族自治州景观生态风险评价和生态安全格局构建[J]. 应用生态学报, 2025, 36(11): 3467-3478.

CHEN Kunlun, LIN Rumeng, CHEN Nenyu, HE Lina, HE Qingjun. Landscape ecological risk assessment and ecological security pattern construction in Chuxiong Yi Autonomous Prefecture, Yunnan Province, China[J]. Chinese Journal of Applied Ecology, 2025, 36(11): 3467-3478.

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