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面向区域滑坡易发性精细化评价的改进斜坡单元法

李星 杨赛 李远耀 殷坤龙 王伟

李星, 杨赛, 李远耀, 殷坤龙, 王伟. 面向区域滑坡易发性精细化评价的改进斜坡单元法[J]. 地质科技通报, 2023, 42(3): 81-92. doi: 10.19509/j.cnki.dzkq.tb20210707
引用本文: 李星, 杨赛, 李远耀, 殷坤龙, 王伟. 面向区域滑坡易发性精细化评价的改进斜坡单元法[J]. 地质科技通报, 2023, 42(3): 81-92. doi: 10.19509/j.cnki.dzkq.tb20210707
Li Xing, Yang Sai, Li Yuanyao, Yin Kunlong, Wang Wei. Improved slope unit method for fine evaluation of regional landslide susceptibility[J]. Bulletin of Geological Science and Technology, 2023, 42(3): 81-92. doi: 10.19509/j.cnki.dzkq.tb20210707
Citation: Li Xing, Yang Sai, Li Yuanyao, Yin Kunlong, Wang Wei. Improved slope unit method for fine evaluation of regional landslide susceptibility[J]. Bulletin of Geological Science and Technology, 2023, 42(3): 81-92. doi: 10.19509/j.cnki.dzkq.tb20210707

面向区域滑坡易发性精细化评价的改进斜坡单元法

doi: 10.19509/j.cnki.dzkq.tb20210707
基金项目: 

国家自然科学基金项目 41877253

详细信息
    作者简介:

    李星(1996—), 女, 现正攻读资源与环境专业硕士学位, 主要从事滑坡地质灾害风险评价方面的研究工作。E-mail: 1850755402@qq.com

    通讯作者:

    李远耀(1978—), 男, 副研究员, 主要从事地质灾害机理与风险分析方面的研究和教学工作。E-mail: liyuanyao2004@163.com

  • 中图分类号: P642.22

Improved slope unit method for fine evaluation of regional landslide susceptibility

  • 摘要:

    易发性评价是区域滑坡灾害风险预警与稳定性分析的基础,针对乡镇尺度的大比例尺精细化滑坡易发性评价,传统基于水文学和地貌学的斜坡单元划分方法难以满足评价精度。针对以上问题,以重庆市万州区大周镇为实例验证对象,形成了适用于精细化评价的改进斜坡单元划分方法。首先从斜坡地质环境孕灾规律出发,综合考虑地形地貌、物质组成、斜坡结构和灾害类型的均一性要求,提出了基于斜坡地质环境一致性的改进斜坡单元划分方法,选择重庆市万州区大周镇为实例验证对象,并与水文分析法、曲率分水岭法进行了对比分析。结果表明:①改进斜坡单元法划分的评价单元大小均匀性较好,未出现细碎单元或畸形长条状单元;②评价单元的总体形态特征更为合理,形态指数集中在1~2之间,呈现圆形或正方形斜坡形态;③改进斜坡单元划分的结果与已有灾害边界范围的叠加重合度最高,能更好地体现滑坡易发性评价或稳定性分析物理意义。研究结论对提高区域滑坡易发性评价的准确性与精度具有重要借鉴意义。

     

  • 图 1  斜坡单元示意图

    Figure 1.  Schematic diagram of the slope unit

    图 2  改进斜坡评价单元划分流程

    Figure 2.  Division process of improved slope evaluation units

    图 3  斜坡地貌单元划分步骤

    Figure 3.  Step of division of slope geomorphic unit

    图 4  斜坡岩组单元划分流程图

    Figure 4.  Flow chart of division of slope rock group units

    图 5  斜坡结构划分示意图

    Figure 5.  Schematic diagram of slope structure division

    图 6  斜坡结构单元划分示意图

    Figure 6.  Schematic diagram of the division of slope structural units

    图 7  大周镇坡向变率

    Figure 7.  Slope aspect variation in Dazhou Town

    图 8  SOA识别出的水库库岸

    Figure 8.  Reservoir banks identified by SOA

    图 9  SOA识别出的小型冲沟

    Figure 9.  Small gullies identified by SOA

    图 10  长度低于约束条件的SOA线段

    Figure 10.  SOA line segment whose length is less than the constraint

    图 11  第四系分布(a)及工程地质岩组(b)

    Figure 11.  Quaternary distribution(a) and engineering geology group(b)

    图 12  研究区岩性产状点(a)与倾向插值结果(b)

    Figure 12.  Lithologic points (a) and dip interpolation results (b) of the study area

    图 13  初始斜坡结构图(a)和降噪后斜坡结构单元(b)

    Figure 13.  Initial slope structure (a) and denoised slope structure unit (b)

    图 14  改进斜坡单元划分过程图

    a.斜坡地貌单元;b.斜坡岩组单元;c.斜坡评价单元

    Figure 14.  Division process of improved slope unit

    图 15  研究区基于水文分析法(a)、曲率分水岭法(b)和改进斜坡单元划分法(c)的划分结果

    Figure 15.  Dividing results based on hydrologic analysis (a), curvature watershed method (b), and improved slope unit method (c)

    表  1  斜坡结构类型划分

    Table  1.   Division of slope structure type

    斜坡结构类型 划分准则
    水平坡 岩层倾角小于10°
    非水平坡 顺向坡 岩层倾角大于10°且岩层倾向与斜坡坡向夹角在30°以内
    斜交坡 岩层倾角大于10°且岩层倾向与斜坡坡向夹角在30°~150°之间
    逆向坡 岩层倾角大于10°且岩层倾向与斜坡坡向夹角在150°~180°之间
    下载: 导出CSV

    表  2  3种斜坡单元划分结果统计表

    Table  2.   Division results of the three slope unit methods

    水文分析法占比/% 曲率分水岭法占比/% 改进斜坡单元划分法占比/%
    分布/ m2 [0, 103) 31.67 1.94 0
    [103, 104) 18.51 10.53 1.87
    [104, 105] 27.76 68.42 71.64
    >105 22.06 19.11 26.49
    形状指数 [1, 1.5) 13.17 43.77 29.10
    [1.5, 2) 25.98 38.23 50.00
    [2, 3) 22.06 13.30 19.03
    [3, 5] 17.79 4.16 1.87
    >5 21.35 0.55 0
    灾害重合度/% < 50 27.27 39.39 3.03
    [50, 75) 24.24 36.36 9.09
    [75, 100) 6.06 12.12 15.15
    100 42.42 12.12 72.73
    下载: 导出CSV
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  • 收稿日期:  2021-11-17

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