院报 ›› 2018, Vol. 35 ›› Issue (7): 51-56.DOI: 10.11988/ckyyb.20170089

• 水土保持与生态建设 • 上一篇    下一篇

基于“3S”技术的南京市水土流失定量监测及分析

梁文广1a, 钱钧1b, 高士佩1b, 王冬梅1a, 徐姗姗2, 杨印1a, 王轶虹1a, 况曼曼1a   

  1. 1.江苏省水利科学研究院 a.湖泊研究所;b.院长办公室,南京 210017;
    2.南京市水务局 农水处,南京 210008
  • 收稿日期:2017-01-23 出版日期:2018-07-01 发布日期:2018-07-12
  • 作者简介:梁文广(1981-),男,河北辛集人,高级工程师,博士,主要从事水利遥感应用研究。E-mail:82335673@qq.com
  • 基金资助:
    江苏省水利科技项目(2013001,2015035,2016029)

Quantitative Monitoring of Soil Erosion Loss in Nanjing by RS, GPS, and GIS

LIANG Wen-guang1, QIAN Jun2, GAO Shi-pei2, WANG Dong-mei1, XU Shan-shan3, YANG Yin1, WANG Yi-hong1, KUANG Man-man1   

  1. 1.Lake Research Department, Hydraulic Research Institute of Jiangsu Province, Nanjing 210017, China;
    2.Administration Office, Hydraulic Research Institute of Jiangsu Province, Nanjing 210017, China;
    3.Department of Agricultural Water Conservancy, Nanjing Water Conservancy Bureau, Nanjing 210008, China
  • Received:2017-01-23 Online:2018-07-01 Published:2018-07-12

摘要: 为定期对南京市水土流失开展动态监测,利用降雨资料、土地利用资料、环境卫星遥感数据、土壤和地形数据,采用“监测水土流失的定量新方法”,计算2011—2015年南京市水土流失。结果表明:①2011—2015年5 a平均南京市水土流失总量为201.42万t,其中,轻度以上水土流失面积为515.75 km2,水土流失量166.77万t,占全市水土流失总量的82.8%,轻度以上水土流失治理仍是水土流失治理中的重点;②5 a中2015年水土流失最严重,2013年则最轻,其中降雨侵蚀力Ri大小为决定因素;③5 a平均极强烈与剧烈水土流失量为分级侵蚀量中最大;④与2001—2010年10 a平均相比,2011—2015年5 a平均南京市微度水土流失面积增加7.6%,轻度以上水土流失面积减少42.5%,轻度以上年水土流失量减少23.7%,CP值的减小是2011—2015年5 a平均水土流失状况改善的主要原因;⑤3次水土流失定量监测表明,2011—2015年监测强烈、极强烈的水土流失面积和年水土流失量减幅下降,剧烈的水土流失面积和年水土流失量增大,主要原因是2011—2015年降雨侵蚀力Ri (5 a)平均值较大。研究成果为南京市水土保持规划和水土流失防治提供了重要的基础数据支撑和科学参考依据。

关键词: 水土流失, 南京市, “3S”技术, 定量监测, 降雨侵蚀

Abstract: A set of novel methods quantitatively monitoring soil erosion loss is employed to calculate the soil erosion loss in Nanjing City in 2011-2015 according to data of rainfall, land use, soil and terrain, and environmental satellite. Results revealed that: (1) From 2011 to 2015, the average total amount of soil erosion loss in Nanjing is 2.014 2 million tons, among which above light level (above level II) soil erosion is 1.667 7 million tons, occupying an area of 515.75 km2 and accounting for 82.8% of the total amount; soil erosion above level II remains a focus of control work. (2) With rainfall erosivity Ri as a decisive factor, the most severe soil erosion happened in 2015, while the slightest in 2013. (3) The five-year average amount of extremely severe (level VI) and severe (level V) soil erosion ranks top among the grading. (4) Compared with ten-year average in 2001-2010, the area of slight (level I) soil erosion in 2011-2015 increased by 7.6%, while the area of erosion above level II reduced by 42.5%, with the amount cut by 23.7%; the decrease in CP(vegetation cover and preservation measure) is the main cause of such mitigation in 2011-2015. (5) In 2011-2015, the decrease in area and amount of level IV and V alleviated; while the area and amount of level VI exacerbated due to large value of rainfall erosivity Ri (five-year average in 2011-2015). The research achievements offer important fundamental data support and scientific basis for the soil and water conservancy planning and soil erosion control in Nanjing City.

Key words: soil erosion loss, Nanjing City, 3S technology, quantitative monitoring, rainfall erosion

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