基于L-THIA模型与3S技术的大亚湾陆域非点源总氮污染研究
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摘要
以大亚湾为研究对象,采用3S(GIS、RS和GPS)技术划分了汇水区范围并处理获得土地利用、土壤水文单元及降水等下垫面信息,运用L-THIA模型(Long-term Hydrologic Impact and Non Point Source Pollutant Model)构建了总氮(TN)这一指标的大亚湾汇水区非点源污染模型,并通过径流量与负荷量模拟结果与不同方法计算结果的比对验证了模型的合理性。结果表明,大亚湾陆域非点源TN年均负荷量为2 559 t;土地利用类型中耕地、建设用地和园地的负荷量和单位面积流失强度均较高,是TN流失的主要土地利用类型;汇水区涉及的11个镇(街)中惠州市稔山镇、平海镇对TN负荷量的贡献合计超过50. 0%,占据了77. 7%的TN流失关键源区,是非点源污染防治需重点关注的区域。来源贡献的定量识别和关键源区的空间识别为大亚湾陆域非点源TN污染的有效控制提供了重要的科学依据。
Based on catchment delineation,land use,soil hydrologic group classification and precipitation data processed by 3 S( GIS,RS and GPS) techniques,a non-point source pollution model for the index of total nitrogen( TN) of Daya Bay was built used the Long-Term Hydrologic Impact and Non Point Source Pollutant model( L-THIA). The model rationality was verified by comparing the modeling results of runoff and load and the results of different methods. It showes that the annual non-point source TN load of Daya Bay was 2 559 tons. The farmland,built-up area and orchard were the main types of land use for TN loss due to the high load and loss intensity. Among 11 towns,Renshan town and Pinghai town contributed more than 50. 0% of TN load and occupied 77. 7% of critical source areas. Thus more attention should be paid to these towns in the work of non-point source pollution control. The quantification of load contribution and the identification of critical source area will help local decision makers to administrate the non-point source nitrogen pollution effectively and efficiently.
Based on catchment delineation,land use,soil hydrologic group classification and precipitation data processed by 3 S( GIS,RS and GPS) techniques,a non-point source pollution model for the index of total nitrogen( TN) of Daya Bay was built used the Long-Term Hydrologic Impact and Non Point Source Pollutant model( L-THIA). The model rationality was verified by comparing the modeling results of runoff and load and the results of different methods. It showes that the annual non-point source TN load of Daya Bay was 2 559 tons. The farmland,built-up area and orchard were the main types of land use for TN loss due to the high load and loss intensity. Among 11 towns,Renshan town and Pinghai town contributed more than 50. 0% of TN load and occupied 77. 7% of critical source areas. Thus more attention should be paid to these towns in the work of non-point source pollution control. The quantification of load contribution and the identification of critical source area will help local decision makers to administrate the non-point source nitrogen pollution effectively and efficiently.
引文
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[25]惠州市水务局.惠州市水资源保护规划[Z].惠州:惠州市水务局,2016.
[2]王友绍,王肇鼎,黄良民.近20年来大亚湾生态环境的变化及其发展趋势[J].热带海洋学报,2004,23(5):85-95.
[3] CHEN Z Z,XU S N,QIU Y S. Using a food-web model to assess the trophic structure and energy flows in Daya Bay,China[J]. Continental Shelf Research,2015,111:316-326.
[4]刘庄,晁建颖,张丽,等.中国非点源污染负荷计算研究现状与存在问题[J].水科学进展,2015,26(3):432-442.
[5]麻德明,石洪华,丰爱平.基于流域单元的海湾农业非点源污染负荷估算:以莱州湾为例[J].生态学报,2014,34(1):173-181.
[6]黄金良,洪华生,张珞平.基于GIS和模型的流域非点源污染控制区划[J].环境科学研究,2006,19(4):119-124.
[7]姚瑞华,王东,赵越,等.非点源污染负荷模型的研究进展[J].水文,2012,32(2):11-15.
[8]毛玉娜,叶爱中,王雪蕾,等.基于GIS-RS的非点源污染模型研究进展[J].北京师范大学学报(自然科学版),2013,49(4):407-416.
[9]王慧亮,孙志琢,李叙勇,等.非点源污染负荷模型的比较与选择[J].环境科学与技术,2013,36(5):176-182.
[10]匡舒雅,李天宏,赵志杰.基于L-THIA模型的四川省濑溪河流域非点源污染负荷分析[J].环境科学研究,2018,31(4):688-696.
[11]白凤姣,李天宏.基于GIS和L-THIA模型的深圳市观澜河流域非点源污染负荷变化分析[J].环境科学,2012,33(8):2 667-2 673.
[12]沈涛,刘良云,马金峰,等.基于L-THIA模型的密云水库地区非点源污染空间分布特征[J].农业工程学报,2007,23(5):62-68.
[13]李凯,曾凡棠,房怀阳,等.基于L-THIA模型的市桥河流域非点源氮磷负荷分析[J].环境科学,2013,34(11):4 218-4 225.
[14]杨柳,吴忠诚,韩瑜,等.基于L-THIA模型的温榆河流域非点源污染负荷变化分析[J].安全与环境学报,2015,15(1):208-213.
[15] HAIKIN S S. Neural networks:a comprehensive foundation[M]. 2nd ed. New Jersey:Prentice Hall,1999.
[16]叶敏婷,王仰麟,彭建,等.基于SOFM网络的云南省土地利用程度类型划分研究[J].地理科学进展,2007,26(2):97-105.
[17] ENGEL B,STORM D,WHITE M,et al. A hydrologic/water quality model application protocol[J]. Journal of the American Water Resources Association,2007,43(5):1 223-1 236.
[18]惠州市水务局.惠州市水资源综合规划[Z].惠州:惠州市水务局,2009.
[19]郑璟,方伟华,史培军,等.快速城市化地区土地利用变化对流域水文过程影响的模拟研究:以深圳市布吉河流域为例[J].自然资源学报,2009,24(9):1 560-1 572.
[20]任秀文,姜国强,刘爱萍,等.大亚湾主要入海河流污染物通量估算研究[C]//中国环境科学学会.2013中国环境科学学会学术年会论文集(第四卷).昆明:中国环境科学学会,2013:1 055-1 064.
[21]袁宇,朱京海,侯永顺,等.污染物入海通量非点源贡献率的分析方法[J].环境科学研究,2008(5):169-172.
[22]邱玲玲.惠州市城市降雨径流氮、磷污染特征研究[J].环境,2012(s2):8-9.
[23]李杨,马晓明.深圳坪山河流域土地利用变化对流域非点源污染负荷的影响[J].水资源保护,2012,28(2):42-45.
[24] MORIASI D N,ARNOLD J G,VAN LIEW M W,et al. Model evaluation guidelines for systematic quantification of accuracy in watershed simulations[J]. Transactions of the ASABE,2007,50(3):885-900.
[25]惠州市水务局.惠州市水资源保护规划[Z].惠州:惠州市水务局,2016.