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中国地质灾害伤亡事件的空间格局及影响因素
Spatial pattern and influencing factors of casualty events caused by landslides

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文摘 对中国2000-2012年造成人员伤亡的地质灾害事件进行分析,其空间分布格局受地形等自然环境要素的影响,南多北少,主要位于川西山区和云贵高原地区,东南丘陵地区,北方黄土丘陵,以及祁连山脉和天山山脉等地区,但局部地区的分布格局表明其还受到人为因素影响。构建基于二元Logistic回归的中国地质灾害伤亡事件发生概率模型(CELC),定量分析自然、人为因素的影响程度,结果表明GDP增长率是仅次于地形起伏度的第二大影响因素,GDP增长率每增加2.72%,地质灾害伤亡事件发生的概率变为原来的2.706倍。此外还有多年平均降水、植被覆盖度、岩性、土壤类型、断裂带、产业类型和人口密度等因素。将CELC模型应用于中国县域,计算各个县的地质灾害伤亡事件概率,发现尚未发生但概率较高的县有27个,或为贫困县、或为矿产工业县域,或为房产过度开发县,它们是未来中国需要重点防范地质灾害的县域。
其他语种文摘 The economy of China has maintained rapid growth with an average annual GDP growth rate of 10.14% (in comparable price) from 2000 to 2012. During this period, China witnessed frequent landslide disasters, including 338,964 identifiable individual landslide disasters that resulted in 45,381 casualties, including 9,928 deaths. Analysis of the casualty events caused by landslides from 2000 to 2012 revealed that the spatial pattern of the casualty events was affected by terrain and other factors of the natural environment, which resulted in the distribution of casualty events being higher in the south region than in the north region. Hotspots of casualty events caused by landslides were in the western Sichuan mountain area and the Yunnan-Guizhou Plateau region, the southeast hilly area, the northern part of the loess hills, and the Qilian and Tianshan Mountains, among some others. However, their local distribution pattern indicated that they were also influenced by economic activity factors. To quantitatively analyze the influence of natural environment factors and human- economic activity factors, the binary logistic regression model was applied. The binary logistic regression model is a type of probabilistic nonlinear regression model describing the relationship between a binary dependent variable and a set of independent variables (explanatory factors). The explanatory factors used in this study included relative relief, mean annual precipitation, vegetation coverage, fault zones, lithology, soil type, GDP growth rate, industry type, and population density. The dependent variable used in this study was the presence (1) or absence (0) of casualty events caused by landslides in the county. For the logistic regression analysis, the continuous variables of relative relief, mean annual precipitation, vegetation coverage, GDP growth rate, and population density were substituted into the model. The categorical variables of fault zones, lithology, soil type, and industry type were transformed into binary dummy variables and then substituted into the model. The Probability Model of Casualty Events Caused by Landslide in China (CELC) was built based on the logistic regression analysis, and the confusion matrix and the receiver operating characteristic (ROC) curve were applied to assess the model performance. The results showed that all explanatory variables in the model were selected based on a significance level of 0.05. The coefficients of the explanatory variables showed that relative relief, GDP growth rate, mean annual precipitation, fault zones, and population density have a positive effect on casualty events caused by landslides. In contrast, vegetation coverage has a negative influence on casualty events caused by landslides. More specifically, the results showed that in terms of the influence degree of casualty events caused by landslides, the GDP growth rate ranks only second to relative relief. The probability of occurrence of casualty events caused by landslides will be 2.706 times that of the previous probability with an increase of GDP growth rate of 2.72%. In the evaluation of the model performance, the correct percentage in the confusion matrix is 75 % and the area under the ROC curve (AUC) is 0.826, revealing that the CELC model has good predictive ability. The CELC model was then applied to calculate the occurrence probability of casualty events caused by landslides for each county in China. The results showed that there are 27 counties with high occurrence probability but zero casualty events caused by landslides. The 27 counties can be divided into three categories: poverty- stricken counties, mineral- rich counties, and realtyoverexploited counties, which are the key areas where great emphasis should be placed on landslides risk reduction.
来源 地理学报 ,2017,72(5):906-917 【核心库】
DOI 10.11821/dlxb201705011
关键词 地质灾害 ; 人员伤亡事件 ; 空间格局 ; 影响因素 ; 县域 ; 中国
地址

北京师范大学, 环境演变与自然灾害教育部重点实验室, 北京, 100875

语种 中文
文献类型 研究性论文
ISSN 0375-5444
学科 地质学
基金 国家自然科学基金项目 ;  国家重点研发计划专项项目课题 ;  “十二五”科技支撑计划项目
文献收藏号 CSCD:5989335

参考文献 共 35 共2页

1.  盛来运. 中国统计年鉴,2013 被引 1    
2.  国务院. 地质灾害防治条例,2004 被引 2    
3.  中国地质环境监测院. 中国崩塌滑坡灾害图,2007 被引 1    
4.  中国地质环境监测院. 中国泥石流灾害图,2007 被引 1    
5.  Eeckhaut M. Statistical modelling of Europe-wide landslide susceptibility using limited landslide inventory data. Landslides,2011,9(3):357-369 被引 8    
6.  Ramani S E. GIS based landslide susceptibility mapping of Tevankarai Ar Subwatershed, Kodaikkanal, India using binary logistic regression analysis. Journal of Mountain Science,2011,8(4):505-517 被引 10    
7.  Garcia-Rodriguez M J. Susceptibility assessment of earthquake-triggered landslides in El Salvador using logistic regression. Geomorphology,2008,95(3/4):172-191 被引 20    
8.  Guzzetti F. Rainfall thresholds for the initiation of landslides in central and southern Europe. Meteorology and Atmospheric Physics,2007,98(3/4):239-267 被引 90    
9.  Ohlmacher G C. Using multiple logistic regression and GIS technology to predict landslide hazard in Northeast Kansas, USA. Engineering Geology,2003,69(3/4):331-343 被引 71    
10.  Atkinson P.M. Generalised linear modelling of susceptibility to landsliding in the Central Apennines, Italy. Computers & Geosciences,1998,24(4):373-385 被引 25    
11.  Ayalew L. Landslide susceptibility mapping using GIS-based weighted linear combination, the case in Tsugawa area of Agano River, Niigata Prefecture, Japan. Landslides,2004,1(1):73-81 被引 29    
12.  黄润秋. 20世纪以来中国的大型滑坡及其发生机制. 岩石力学与工程学报,2007,26(3):433-454 被引 432    
13.  Ayalew L. The application of GIS-based logistic regression for landslide susceptibility mapping in the Kakuda-Yahiko Mountains, central Japan. Geomorphology,2005,65(1/2):15-31 被引 93    
14.  Jadda M. PFR model and GiT for landslide susceptibility mapping:A case study from central Alborz, Iran. Natural Hazards,2011,57(2):395-412 被引 4    
15.  李媛. 中国地质灾害类型及其特征—基于全国县市地质灾害调查成果分析. 中国地质灾害与防治学报,2004,15(2):29-34 被引 75    
16.  中国国土资源部. 地质灾害灾情险情报告 被引 1    
17.  中国地质环境监测院. 全国地质灾害通报(2004-2012). 中国地质环境信息网 被引 1    
18.  民政部国家减灾中心. 昨日灾情,2004/2012 被引 1    
19.  中国科学院计算机网络信息中心. 地理空间数据云 被引 3    
20.  中国科学院地理科学与资源研究所. 地球系统科学数据共享平台 被引 1    
引证文献 15

1 张英杰 地质灾害易发区农村居民点布局优化研究:以浙江洞头为例 生态与农村环境学报,2019,35(11):1387-1395
被引 3

2 季建万 基于多参数优选地理探测器的京津冀城市群地质灾害影响因子分析 地理与地理信息科学,2023,39(2):39-45
被引 0 次

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论文科学数据集

1. 横断山区(川藏铁路)自然灾害风险及综合风险评估数据集(2020)

2. “一带一路”沿线65个国家自然灾害数据(1900-2018)

3. 祁连山-阿尔金山区250米分辨率地质灾害危险性图(2022)

数据来源:
国家青藏高原科学数据中心

1. 北京市六环以内商业区分布与分类研究数据集

2. 岷江上游地区生境适宜性评价数据集

数据来源:
国家对地观测科学数据中心
PlumX Metrics
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