基于Google Earth Engine的不同开采模式下矿区土地利用变化生态环境效应

doi:10.6046/zrzyyg.2024038

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摘要为探究不同开采模式下矿区土地利用变化的生态环境效应,该文以淮南市顾桥煤矿(井工开采)和马鞍山市南山铁矿(露天开采)为研究区,基于谷歌地球引擎(Google Earth Engine,GEE)云计算平台,耦合绿度、热度、干度、湿度构建遥感生态指数(remote sensing ecological index,RSEI),对2种不同开采模式矿区的生态环境质量进行评价,并分别分析其2000—2020 年间土地利用变化和生态环境质量之间动态演变规律。结果表明: ①井工开采和露天开采矿区的耕地占比最大,井工开采矿区水域面积扩大显著,露天开采矿区以耕地、林地减少和建设用地增加为主; ②2个矿区生态环境质量整体维持一般及良好态势,顾桥煤矿RSEI值分别为 0.60,0.82,0.71,0.65和0.68,南山铁矿RESI值分别为0.58,0.59,0.59,0.63和0.64,不同土地利用类型中,建设用地和水体部分生态环境较差,林地和耕地生态环境较优; ③井工开采模式矿区地表沉降,耕地向水域转变,导致生态环境质量变差,而露天开采模式矿区剥离土体,林地和耕地面积减少以及建设用地增加是露天矿生态环境变差的原因。

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关键词 ：井工开采, 露天开采, 谷歌地球引擎, 土地利用变化, 遥感生态指数

Abstract：

To investigate the ecological and environment effects of land-use changes under different mining modes, this study utilized the Google Earth Engine (GEE) cloud computing platform to construct a remote sensing ecological index (RSEI) by integrating the greenness, heat, dryness, and wetness indicators. The RSEI was utilized to assess the ecological quality of two mining areas with different mining modes: the Guqiao Coal Mine in Huainan City (underground mining) and the Nanshan Iron Mine in Ma’anshan City (open-pit mining). Through a comparative analysis of relevant data from 2000 to 2020, this study analyzed the dynamic evolutionary patterns between land use changes and ecological quality in the two mining areas. The results indicate that cultivated land occupied the largest proportion in both mining areas. The underground mining area was characterized by a significantly expanded water area, whereas the open-pit mining area featured reduced cultivated and forest lands and increased construction land. Both mining areas exhibited overall good-to-fair ecological quality. Specifically, the RSEI values for the Guqiao Coal Mine were 0.60, 0.82, 0.71, 0.65, and 0.68, while those for the Nanshan Iron Mine were 0.58, 0.59, 0.59, 0.63, and 0.64. Among various land use types, construction land and water bodies displayed relatively poor ecological conditions, whereas forest and cultivated lands exhibited more favorable conditions. The underground mining area showed surface subsidence and the transition of cultivated land to water areas, leading to deteriorating ecological quality. In contrast, the open-pit mining area showed soil stripping, shrinking forest and cultivated lands, and construction land expansion, contributing significantly to the declining ecological quality.

Key words： underground mining open-pit mining Google Earth Engine (GEE) land use change remote sensing ecological index (RSEI)

收稿日期: 2024-01-20 出版日期: 2025-07-01

ZTFLH:

TP79

基金资助:中国工程院战略研究与咨询项目“周边国家矿产资源状况及开发利用合作战略研究”(2024-XZ-28);国家重点研发项目“非煤矿山重大安全风险智能预警技术及示范”(2021YFC3001300)

通讯作者: 聂闻(1982-),男,博士,研究员,主要从事地质矿山灾害预测预警研究。Email: wen.nie@vip.tom.com。

作者简介: 林欣源(1999-),女,硕士研究生,主要从事环境监测和评价研究。Email: lxyfuz@163.com。

引用本文:

林欣源, 程扬健, 谢伟, 李传庆, 聂闻. 基于Google Earth Engine的不同开采模式下矿区土地利用变化生态环境效应[J]. 自然资源遥感, 2025, 37(3): 54-64.
LIN Xinyuan, CHENG Yangjian, XIE Wei, LI Chuanqing, NIE Wen. Exploring the ecological effects of land use changes in mining areas under different mining modes based on the Google Earth Engine. Remote Sensing for Natural Resources, 2025, 37(3): 54-64.

链接本文:

https://www.gtzyyg.com/CN/10.6046/zrzyyg.2024038 或 https://www.gtzyyg.com/CN/Y2025/V37/I3/54

Fig.1 研究区地理位置

Fig.2 研究方法流程图

Tab.1 多维分类特征集

指数	计算公式	解释
NDVI	$(B N I R - B r e d) / (B N I R + B r e d)$	式中:B_NIR,B_red,B_blue,B_green,B_SWIR1,B_SWIR2分别为近红外、红光、蓝光、绿光、短波红外1和2波段的反射率^[16-17];SI^[18]和IBI^[19]分别为裸土指数和建筑指数;λ为TIR波段的中心波长;T为传感器探测到的亮温温度; $ε$ 为地表比辐射率;ρ = 1.438 × 10^-2 m·K。
WET	$W E T T M = 0.0315 B b l u e + 0.2021 B g r e e n + 0.3102 B r e d + 0.1594 B N I R - 0.6806 B S W I R 1 - 0.6109 B S W I R 2 W E T O L I = 0.1511 B b l u e + 0.1973 B g r e e n + 0.3283 B r e d + 0.3407 B N I R - 0.7117 B S W I R 1 - 0.4559 B S W I R 2$
NDBSI	$(S I + I B I) / 2$
LST	$T / [1 + (λ T / ρ) l n ε] - 273.15$

Tab.2 遥感指数计算公式

Tab.3 顾桥煤矿和南山铁矿特征变量重要性

Fig.3 顾桥煤矿和南山铁矿土地利用分类精度

Tab.4 顾桥煤矿各土地利用类型面积

Tab.5 南山铁矿各土地利用类型面积

Fig.4 顾桥煤矿土地利用分类结果

Fig.5 南山铁矿土地利用分类结果

Tab.6 顾桥煤矿和南山铁矿4个指标PC1载荷

Fig.6 2000—2020年顾桥煤矿和南山铁矿RSEI

Fig.7-1 顾桥煤矿生态质量分级及面积统计

Fig.7-2 顾桥煤矿生态质量分级及面积统计

Fig.8 南山铁矿生态质量分级及面积统计

Tab.7 2000—2020年顾桥煤矿和南山铁矿RSEI趋势变化面积占比

Fig.9 2000—2020年顾桥煤矿和南山铁矿RSEI趋势分析

Fig.10 顾桥煤矿和南山铁矿土地利用转移类型生态贡献率

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