Spatial scale effects of landscape patterns on non-point source pollution: A case study of Taizi River Basin in Northeast China

doi:10.13287/j.1001-9332.202404.022

Abstract

Abstract: River water quality is influenced by natural processes and human activities. Multi-scale landscape patterns can affect river water quality by altering the generation and transport processes of pollutants at different spatial scales. Taking Taizi River Basin in Northeast China as an example, we analyzed the relationship between landscape patterns and non-point source pollution in rivers based on water quality monitoring data and land use data by using correlation analysis and redundancy analysis methods. We aimed to determine the key spatial scales for the responses of landscape patterns to non-point source pollution and identify the key landscape indices influencing river non-point source pollution. The results showed that water quality of Taizi River Basin had seasonal differences, with better water quality during the flood season than non-flood season. Spatially, total nitrogen (TN) and total phosphorus (TP) were higher at the confluence points of tributaries and downstream areas. The impact of landscape patterns on non-point source pollution was stronger during the non-flood season than the flood season, while the influence on TN was stronger than on TP. At the spatial scale of within 500 m buffer zone during the flood season and at the sub-watershed scale during the non-flood season, landscape patterns showed the highest explanatory power for the variations of TN and TP. At the type level, built-up land, cropland, and bare land were positively correlated with TN and TP, while forest was negatively correlated with TN and TP, which were the key types influencing non-point source pollution. At the landscape level, patch density, percentage of like adjacencies, and contagion index were key indicators affecting watershed water quality. Lower patch density was associated with better connectivity and aggregation of “sink” landscapes, leading to better purification effects on TN, but more pronounced retention effects on TP. Conversely, higher landscape diversity and denser pattern of multiple types would cause the deterioration of water quality. Our results suggested that rational allocation of landscape types within the watershed and riparian buffer zones, appropriately enriching landscape diversity, and optimizing landscape aggregation and connectivity would be effective measures for improving water quality and achieving sustainable ecological management.

Key words: landscape pattern, non-point source pollution, spatial scale effect, Taizi River Basin

LYU Leting, ZHENG Xiaoyu, LIU Qi, SUN Caizhi, BI Siqi. Spatial scale effects of landscape patterns on non-point source pollution: A case study of Taizi River Basin in Northeast China[J]. Chinese Journal of Applied Ecology, 2024, 35(4): 1112-1122.

References

[1] 王国波, 陈磊, 肖月晨, 等. 基于文献计量的非点源污染研究趋势及热点分析. 中国农学通报, 2015, 31(23): 251-260
[2] 李俊然, 陈利顶, 郭旭东, 等. 土地利用结构对非点源污染的影响. 中国环境科学, 2000, 20(6): 506-510
[3] Wu JH, Lu J. Spatial scale effects of landscape metrics on stream water quality and their seasonal changes. Water Research, 2021, 191: 116811
[4] Shi P, Zhang Y, Li ZB, et al. Influence of land use and land cover patterns on seasonal water quality at multi-spatial scales. Catena, 2016, 151: 182-190
[5] Ngowari J, Monday M, Eton C, et al. Landscape variability of riparian buffers and its impact on soil and water chemistry of an urbanized watershed. Ecological Indicators, 2022, 137: 108777
[6] Dou JH, Xia R, Chen Y, et al. Mixed spatial scale effects of landscape structure on water quality in the Yellow River. Journal of Cleaner Production, 2022, 368: 133008
[7] Zhang Y, Granger SG, Semenov MA, et al. Diffuse water pollution during recent extreme wet-weather in the UK: Environmental damage costs and insight into the future? Journal of Cleaner Production, 2022, 338: 130633
[8] Liu HY, Meng C, Wang Y, et al. From landscape perspective to determine joint effect of land use, soil, and topography on seasonal stream water quality in subtropical agricultural catchments. Science of the Total Environment, 2021, 783: 147047
[9] 邬建红. 水源区非点源氮污染的定量溯源、分类减排与景观格局调控研究. 博士论文. 杭州: 浙江大学, 2021
[10] Liu J, Yan TZ, Bai JW, et al. Integrating source apportionment and landscape patterns to capture nutrient variability across a typical urbanized watershed. Journal of Environmental Management, 2023, 325: 116559
[11] 刘可暄, 王冬梅, 常国梁, 等. 多空间尺度景观格局与地表水质响应关系研究. 环境科学学报, 2022, 42(2): 23-31
[12] Chen LW, Yang YT, Ding MJ, et al. Scale effects of multi-medium heavy metals in response to landscape indices in the Yuan River, China. Journal of Cleaner Production, 2022, 373: 133784
[13] Liu HY, Meng C, Wang Y, et al. Multi-spatial scale effects of multidimensional landscape pattern on stream water nitrogen pollution in a subtropical agricultural watershed. Journal of Environmental Management, 2022, 321: 115962
[14] 朱爱萍, 原升艳, 温姗姗, 等. 不同空间尺度的景观格局对流溪河水质的影响. 生态学报, 2023, 43(4): 1485-1495
[15] Xu S, Li SL, Zhong J, et al. Spatial scale effects of the variable relationships between landscape pattern and water quality: Example from an agricultural karst river basin, Southwestern China. Agriculture, Ecosystems and Environment, 2020, 300: 106999
[16] Ding J, Jiang Y, Liu Q, et al. Influences of the land use pattern on water quality in low-order streams of the Dongjiang River basin, China: A multi-scale analysis. Science of the Total Environment, 2016, 551-552: 205-216
[17] 吕乐婷, 高晓琴, 刘琦, 等. 东江流域景观格局对氮、磷输出的影响. 生态学报, 2021, 41(5): 1758-1765
[18] 张金屯, 邱扬, 郑凤英. 景观格局的数量研究方法. 山地学报, 2000, 18(4): 346-352
[19] 陈文波, 肖笃宁, 李秀珍. 景观指数分类、应用及构建研究. 应用生态学报, 2002, 13(1): 121-125
[20] 张柳柳, 刘睿, 张静, 等. 长江上游坡地景观特征对河流水质的影响. 生态学报, 2022, 42(16): 6704-6717
[21] 王孟文, 齐伟, 王鹏涛, 等. 鲁东山区流域景观格局与面源污染关联关系. 自然资源学报, 2020, 35(12): 3007-3017
[22] Li NX, Xu JF, Yin W, et al. Effect of local watershed landscapes on the nitrogen and phosphorus concentrations in the waterbodies of reservoir bays. Science of the Total Environment, 2020, 716: 137132
[23] 杨强强, 徐光来, 杨先成, 等. 青弋江流域土地利用/景观格局对水质的影响. 生态学报, 2020, 40(24): 9048-9058
[24] 吕乐婷, 乔皓, 郑德凤, 等. 太子河流域景观格局时空演变及其对水源涵养的影响. 水资源保护, 2023, 39(6): 111-120
[25] 田晶. 气候变化下浑太流域污染负荷的响应特征研究. 硕士论文. 大连: 大连理工大学, 2023
[26] 赵洪武, 范宏. 太子河流域汛期水资源利用研究. 东北水利水电, 2003(11): 9-10
[27] 张微微, 李晓娜, 王超, 等. 密云水库上游白河地表水质对不同空间尺度景观格局特征的响应. 环境科学, 2020, 41(11): 4895-4904
[28] 胡琳, 李思悦. 不同空间尺度土地利用结构与景观格局对龙川江流域水质的影响. 生态环境学报, 2021, 30(7): 1470-1481
[29] Zhong XC, Xu QL, Yi JH, et al. Study on the threshold relationship between landscape pattern and water quality considering spatial scale effect: A case study of Dianchi Lake Basin in China. Environmental Science and Pollution Research, 2022, 29: 44103-44118
[30] 国家环境保护总局. 地表水环境质量标准(GB 3838—2002). 北京: 国家环境保护总局, 2002
[31] 范雅双, 于婉晴, 张婧, 等. 太湖上游水源区河流水质对景观格局变化的响应关系: 以东苕溪上游为例. 湖泊科学, 2021, 33(5): 1478-1489
[32] 李好好, 黄懿梅, 郭威, 等. 河湟谷地不同时空尺度下土地利用及空间格局对水质的影响. 环境科学, 2022, 43(8): 4042-4053
[33] 张志敏, 杜景龙, 陈德超, 等. 典型网状河网区域土地利用和景观格局对地表季节水质的影响: 以江苏省溧阳市为例. 湖泊科学, 2022, 34(5): 1524-1540
[34] Shi JH, Jin R, Zhu WH, et al. Effects of multi-scale landscape pattern changes on seasonal water quality: A case study of the Tumen River Basin in China. Environmental Science and Pollution Research, 2022, 29: 76847-76863
[35] 朱颖, 王怡, 贺风春, 等. 景观格局对阳澄湖小流域水质变化影响的空间尺度效应. 水土保持通报, 2021, 41(2): 105-113
[36] 陈优良, 邹文敏, 刘星根, 等. 东江源流域不同空间尺度景观格局对水质影响分析. 环境科学, 2022, 43(11): 5053-5063
[37] 范雅双. 流域景观格局对河流水质的影响分析: 以东苕溪上游为例. 硕士论文. 杭州: 浙江农林大学, 2020
[38] 李艳利, 李艳粉, 徐宗学, 等. 浑太河上游流域河岸缓冲区景观格局对水质的影响. 生态与农村环境学报, 2015, 31(1): 59-68
[39] Donohue I, Mcgarrigle ML, Mills P. Linking catchment characteristics and water chemistry with the ecological status of Irish rivers. Water Research, 2005, 40: 91-98
[40] 赵鹏, 夏北成, 秦建桥, 等. 流域景观格局与河流水质的多变量相关分析. 生态学报, 2012, 32(8): 2331-2341
[41] 宋静雯, 张学霞, 姜东旸, 等. 不同尺度土地利用方式对地表水环境质量的影响及驱动机制. 环境科学, 2022, 43(6): 3016-3026