Ecological environment quality evaluation based on water benefit-based ecological index in Guangdong Province, China

doi:10.13287/j.1001-9332.202410.023

Abstract

Abstract: As one of the provinces with the largest number of national forest cities, all prefecture-level cities in Guangdong Province have joined the campaigns of building forest cities. Mastering the spatial and temporal variations of ecological environment quality (EEQ) in Guangdong Province is conducive to the benign interaction and coordinated development of urban construction and ecosystem. We used the water benefit-based ecological index (WBEI) to achieve rapid monitoring of EEQ in Guangdong Province, utilized the standard deviation ellipse and gravity center migration, Theil-Sen Median trend method and Mann-Kendall test to explore the spatial distribution disparities and trends, and analyzed the coupling coordination between EEQ and urbanization. The results showed that the WBEI derived from the normalized difference vegetation index could better reflect vegetation coverage in Guangdong Province, and objectively evaluate the EEQ of watersheds and urban vegetation zones. The EEQ in the northern inland area was generally better than that in the southern coastal area, and it was more concentrated in the southwest-northeast direction. The gravity center position displayed a sequential movement from southwest to northeast and then back to southwest. Most prefecture-level cities remained stable or improved in EEQ, while the improved and degraded types were distributed in various regions of the province. The coupling coordination degree between EEQ and urbanization in southern Guangdong Province exceeded that of the northern region, with the coupling coordination degree being constantly improving. The Pearl River Delta Forest City Cluster emerged as a region characterized by high levels of coupling coordination, with a good radiation driving effect in promoting the coordination of EEQ and urban construction. This study could provide a method reference for EEQ evaluation within multi-watershed forest cities.

Key words: ecological environment quality, water benefit-based ecological index, coupling coordination degree model, Guangdong Province

HU Landi, TAN Juan, CHEN Chulin, SHE Jiyun. Ecological environment quality evaluation based on water benefit-based ecological index in Guangdong Province, China[J]. Chinese Journal of Applied Ecology, 2024, 35(10): 2861-2871.

References

[1] Liao WH, Jiang WG. Evaluation of the spatiotemporal variations in the eco-environmental quality in China based on the remote sensing ecological index. Remote Sensing, 2020, 12: 2462
[2] 窦世卿, 张楠, 靖娟利, 等. 基于耦合模型的广东省生态系统健康时空动态变化. 科学技术与工程, 2022, 22(27): 12223-12232
[3] Long Y, Jiang FG, Deng ML, et al. Spatial-temporal changes and driving factors of eco-environmental quality in the Three-North region of China. Journal of Arid Land, 2023, 15: 231-252
[4] 冯平, 杨妮娟, 李建柱. 滦河流域遥感生态指数改进及生态环境质量评价. 应用生态学报, 2023, 34(12): 3195-3202
[5] 安骐岷, 员学锋, 陈锦鸿, 等. 陕西省城镇化与生态环境质量时空交互关系研究. 水土保持研究, 2024, 31(2): 1-12
[6] 刘冬冬, 潘萍, 付佳, 等. 2000—2020年赣南植被覆盖时空变化特征及驱动因素. 应用生态学报, 2023, 34(11): 2919-2928
[7] 排日海·合力力, 昝梅. 干旱区绿洲城市生态环境时空格局变化及影响因子研究. 自然资源遥感, 2023, 35(3): 201-211
[8] 丁雪, 冯婧文, 黄园园, 等. 2000—2020年滇中城市群生态环境质量动态监测及空间格局演变. 水土保持通报, 2023, 43(3): 96-104
[9] 赵敏敏, 何志斌, 蔺鹏飞, 等. 基于压力-状态-响应模型的黑河中游张掖市生态安全评价. 生态学报, 2021, 41(22): 9039-9049
[10] 姜晟, 王甜甜, 蔡琨, 等. “十四五”生态质量评价办法应用研究与讨论: 以江苏省宜兴市为例. 环境监控与预警, 2022, 14(3): 82-87
[11] 徐涵秋. 城市遥感生态指数的创建及其应用. 生态学报, 2013, 33(24): 7853-7862
[12] Ling HB, Guo B, Yan JJ, et al. Enhancing the positive effects of ecological water conservancy engineering on desert riparian forest growth in an arid basin. Ecological Indicators, 2020, 118: 106797
[13] Mark JM, Amy KH. Adaptation and adaptedness of organisms to urban environments. Annual Review of Eco-logy, Evolution, and Systematics, 2015, 46: 261-280
[14] Jiao ZJ, Sun GY, Zhang AZ, et al. Water benefit-based ecological index for urban ecological environment quality assessments. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2021, 14: 7557-7569
[15] Wu YZ, Shi KF, Chen ZQ, et al. Developing improved time-series DMSP-OLS-Like data (1992-2019) in China by integrating DMSP-OLS and SNPP-VIIRS. IEEE Transactions on Geoscience and Remote Sensing, 2022, 60: 4407714
[16] Yang J, Huang X. The 30 m annual land cover dataset and its dynamics in China from 1990 to 2019. Earth System Science Data, 2021, 13: 3907-3925
[17] 周寅桥, 李雄. 基于水体型生态指数的无锡市城区生态质量时空变化分析. 生态学报, 2024, 44(4): 1-15
[18] Zhang ZM, Fan YG, Jiao ZJ. Wetland ecological index and assessment of spatial-temporal changes of wetland ecological integrity. Science of the Total Environment, 2023, 862: 160741
[19] Liou YA, Le MS, Chen H. Normalized difference latent heat index for remote sensing of land surface energy fluxes. IEEE Transactions on Geoscience and Remote Sensing, 2019, 57: 1423-1433
[20] 姚尧, 王世新, 周艺, 等. 生态环境状况指数模型在全国生态环境质量评价中的应用. 遥感信息, 2012, 27(3): 93-98
[21] 王淑佳, 孔伟, 任亮, 等. 国内耦合协调度模型的误区及修正. 自然资源学报, 2021, 36(3): 793-810
[22] 关翠柳, 闻德保, 李雨豪, 等. 广东省1980—2018年“三生”用地转型对生态环境质量的影响. 水土保持通报, 2021, 41(4): 241-251
[23] 王秀明, 张勇, 奚蓉, 等. 广东省城镇化与生态环境耦合协调的空间特征及影响因素研究. 中国环境管理, 2019, 11(3): 100-106
[24] 林森, 林先扬, 徐明威. 区域生态保护与经济发展耦合作用关系研究: 基于广东省的实证分析. 金融经济, 2023(9): 73-82
[25] 陈津乐, 张锦水, 段雅鸣, 等. 中分辨率遥感影像云检测与厚云去除研究综述. 遥感技术与应用, 2023, 38(1): 143-155
[26] Rocchini D, Boyd DS, Féret JB, et al. Satellite remote sensing to monitor species diversity: Potential and pitfalls. Remote Sensing in Ecology and Conservation, 2016, 2: 25-36