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学术论文:
(2023年)
[1] Huang Y,Xu C*, Li L, He X, Cheng J, Xu X, Li J, Zhang X (2023) Inventory
and spatial distribution of ancient landslides in Hualong County, China.
Land, 12(1): 136. doi:10.3390/land12010136
[2] Xiao Z,Xu C*, Huang Y, He X, Shao X, Chen Z, Xie C, Li T, Xu X (2023)
Analysis of spatial distribution of landslides triggered by the Ms 6.8 Luding
earthquake in China on September 5, 2022. Geoenvironmental Disasters, 10: 3. doi:10.1186/s40677-023-00233-w
[3] Shao X, Ma S,Xu C*(2023) Distribution and characteristics of shallow
landslides triggered by the 2018 Mw 7.5 Palu earthquake, Indonesia.
Landslides, 20(1): 157-175.
[4] Ma S, Shao X,Xu C*, Xu Y (2023) Insight from a physical-based model for the
triggering mechanism of loess landslides induced by the 2013 Tianshui heavy
rainfall event. Water, 15(3): 443. doi: 10.3390/w15030443
[5] Huang Y,Xu C*, Zhang X, Li L, Xu X (2023) Research in the field of
natural hazards based on bibliometric analysis. Natural Hazards Review,
24(2): 04023012.
[6] Huang Y, Xie C, Li T,Xu C*, He X, Shao X, Xu X, Zhan T,
Chen Z (2023) An open-accessed inventory of landslides triggered by the Ms
6.8 Luding earthquake, China on September 5, 2022. Earthquake Research Advances,
3(1): 100181.
[7] Ma S, Shao X,Xu C*(2023) Landslide susceptibility mapping in terms of the
slope-unit or raster-unit, which is better? Journal of Earth Science,
[8] Yang J,Xu C*, Wang J, Jing X (2023) Joint effects and spatiotemporal
characteristics of the driving factors of landslides in earthquake areas.
Journal of Earth Science,
[9] Cui Y, Yang W,Xu C*, Wu S (2023) Distribution of ancient landslides and
landslide hazard assessment in the Western Himalayan Syntaxis area. Frontiers
in Earth Science, 11(Article 1135018): 15 pages.
[10] He X, Huang Y, Chen Z, Li L, Wang W,
Wang X, Xu C* (2023) Report on the second academic forum on earthquake hazard
chain, 12 November 2022, Beijing, China. Natural Hazards Research,
[11] Chen J, Li L,Xu C*, Huang Y, Luo Z, Xu X, Lyu Y (2022) Freely accessible
inventory and spatial distribution of large-scale landslides in Xianyang
City, Shaanxi Province, China. Earthquake Research Advances,
[12] Shah AA*, Ullah A, Khan NA, Khan A,
Tariq MAUR,Xu C*(2023) Community
social barriers to non-technical aspects of flood early warning systems and
NGO-led interventions: The case of Pakistan. Frontiers in Earth Science,
11(Article 1068721): 15 pages.
[13] Shah AA*, Ullah A, Khan NA, Shah MH,
Ahmed R, Hassan ST, Tariq MAUR,Xu C*(2023) Identifying obstacles encountered at different stages of the disaster
management cycle (DMC) and its implications for rural flooding in Pakistan.
Frontiers in Environmental Science, 11(Article 1088126): 14 pages.
[14] Wen H, Li W,Xu C*, Daimaru H (2023) Editorial Landslides in forests around
the world: Causes and mitigation. Forests, 14(3): 629.
[15] Guo Z, Tian B, He J*,Xu C, Zeng T, Zhu Y (2023) Hazard
assessment for regional typhoon-triggered landslides by using
physically-based model – a case study from southeastern China. Georisk:
Assessment and Management of Risk for Engineered Systems and Geohazards,
[16] Jin J, Cui Y*,Xu C, Zheng J, Miao H (2023) Application of logistic regression
model for hazard assessment of landslides caused by the 2012 Yiliang Ms 5.7
earthquake in Yunnan Province, China. Journal of Mountain Science, 20(3):
657-669.
[17] Bai Y*,Xu C(2023) The qualitative analyses of correlations between
strong ground motions of the three large earthquakes and landslide
distributions. Journal of Earth Science,
[18] Cheng J*,Xu C, Ma J, Xu X, Zhu P (2023) From active fault segmentation to
risks of earthquake hazards and property and life losses – A case study from
the Xianshuihe-Xiaojiang Fault Zone. Science China Earth Sciences,
[19] 张迎宾,徐佩依,林剑锋,伍新南,柳静,相晨琳,何云勇,杨昌凤,许冲(2022)基于BP神经网络的地震滑坡危险性评价——以九寨沟为例.工程地质学报,
[20] 齐文文,许冲*(2022)多云地区地震滑坡遥感识别研究.地震学报,
[21] 程佳*,许冲,马健,徐锡伟,朱鹏宇(2022)从活动断层分段到地震地质灾害与财产人口损失风险——以鲜水河-小江断裂带为例.中国科学:地球科学,
(2022年)
[22] Shao X,Xu C*, Ma S (2022) Preliminary analysis of coseismic landslides
induced by the 1 June 2022 Ms 6.1 Lushan earthquake, China. Sustainability,
14(24): 16554.
[23] Wang P, Li L,Xu C*, Zhang Z, Xu X (2022) An open source inventory and spatial
distribution of landslides in Jiyuan City, Henan Province, China. Natural
Hazards Research, 2(4): 325-330.
[24] Huang Y, Li L,Xu C*, Cheng J, Xu X, Zheng T, Zhang X (2022) Spatiotemporal
distribution patterns of deadly geohazard events in China, 2013–2019. Natural
Hazards Research, 2(4): 316-324.
[25] Shao X,Xu C*, Wang P, Li L, He X, Chen Z, Huang Y, Xu X (2022) Two public
inventories of landslides induced by the 10 June 2022 Maerkang Earthquake
swarm, China and ancient landslides in the affected area. Natural Hazards
Research, 2(4): 269-272.
[26] Shao X,Xu C*(2022) Earthquake-induced landslides susceptibility
assessment: A review of the state-of-the-art. Natural Hazards Research, 2(3):
172-182.
[27] He X,Xu C*(2022) Spatial distribution and tectonic significance of
the landslides triggered by the 2021 Ms6.4 Yangbi Earthquake, Yunnan, China.
Frontiers in Earth Science, 10(Article 1030417): 17 pages.
[28] Ma S, Shao X,Xu C*(2022) Characterizing the distribution pattern and a
physically based susceptibility assessment of shallow landslides triggered by
the 2019 heavy rainfall event in Longchuan County, Guangdong Province, China.
Remote Sensing, 14(17): 4257.
[29] Yang Z,Xu C*, Shao X, Ma S, Li L (2022) Landslide susceptibility mapping
based on CNN-3D algorithm with attention module embedded. Bulletin of
Engineering Geology and the Environment, 81(10): 412.
[30] Li L,Xu C*, Yang Z, Zhang Z, Lv M (2022) An inventory of large-scale
landslides in Baoji City, Shaanxi Province, China. Data, 7(8): 114.
[31] Li L,Xu C*, Yao X, Shao B, Ouyang J, Zhang Z, Huang Y (2022)
Large-scale landslides around the reservoir area of Baihetan hydropower
station in Southwest China: Analysis of the spatial distribution. Natural
Hazards Research, 2(3): 218-229.
[32] Xu C*, Gorum T, Tanyas H (2022) Editorial:
Application of Remote Sensing and GIS in earthquake-triggered landslides.
Frontiers in Earth Science, 10(Article 964753): 5 pages.
[33] Yang Z,Xu C*, Li L (2022) Landslide detection based on ResU-Net with
transformer and CBAM embedded: Two examples with geologically different
environments. Remote Sensing, 14(12): 2885.
[34] Yang Z,Xu C*(2022) Efficient detection of earthquake-triggered
landslides based on U-Net++: An example of the 2018 Hokkaido Eastern Iburi
(Japan) Mw = 6.6 Earthquake. Remote Sensing, 14(12): 2826.
[35] Zhang X, Li L,Xu C*(2022) Large-scale landslide inventory and their mobility
in Lvliang City, Shanxi Province, China. Natural Hazards Research, 2(2):
111-120.
[36] He X,Xu
C*, Xu X, Yang Y (2022) Advances on the avoidance zone and buffer zone of
active faults. Natural Hazards Research, 2(2): 62-74.
[37] Wu X,Xu C*, Xu X, Chen G, Zhu A, Zhang L, Yu G, Du K (2022) A Web-GIS
hazards information system of the 2008 Wenchuan Earthquake in China. Natural
Hazards Research, 2(3): 210-217.
[38] Huang Y,Xu C*, Zhang X, Li L (2022) Bibliometric analysis of landslide
research based on the WOS database. Natural Hazards Research, 2(2): 49-61.
[39] Li L,Xu C*, Xu X, Zhang Z, Cheng J (2022) Inventory and distribution
characteristics of large-scale landslides in Baoji City, Shaanxi Province,
China. ISPRS International Journal of Geo-Information, 11(1): 10.
[40] He X,Xu C*, Wang W, Wang X (2022) Report on the establishment meeting
of Committee on Earthquake Hazard Chain, Seismological Society of China and
the first academic forum, 21-22 August 2021, Beijing, China. Natural Hazards
Research, 2(1): 41-47.
[41] Cui Y*, Hu J,Xu C*, Miao H, Zheng J (2022) Landslides triggered by the 1970 Ms
7.7 Tonghai earthquake in Yunnan, China: an inventory, distribution
characteristics, and tectonic significance. Journal of Mountain Science,
19(6): 1633-1649.
[42] Jiang H*,Xu C, Adhikari BR, Liu X, Tan X, Yuan RM (2022) Editorial:
Environmental change driven by climatic change, tectonism, and landslide.
Frontiers in Earth Science, 10(Article 1076801): 4 pages.
[43] Sarfraz Y*,
Basharat M, Riaz MT, Akram MS, Xu C, Ahmed KS, Shahzad A, Al-Ansari N, Linh
NTT* (2022) Application of statistical and machine learning techniques for
landslide susceptibility mapping in the Himalayan road corridors. Open
Geosciences, 14(1): 1606-1635.
[44] Zhang D, Yang W*,Xu C, Ye T, Liu Q (2022) Extracting deforming landslides from
time-series Sentinel-2 imagery. Landslides,19(11):
2761-2774.
[45] Yu B,Xu C, Chen F, Wang N, Wang L*
(2022) HADeenNet: A hierarchical-attention multi-scale deconvolution network
for landslide detection. International Journal of Applied Earth Observation
and Geoinformation, 111: 102853.
[46] Xiao Z*, Ding W, Hao S, Wang Z,Xu C, Gao H, Zhang X (2022)
Quantitative evaluation of reservoir heterogeneity in the Ordos Basin based
on Tamura texture features. Frontiers in Earth Science, 11(Article 922608):
18 pages.
[47] Yu B, Wang N,Xu C, Chen F, Wang L* (2022) A network for landslide detection
using large-area remote sensing images with multiple spatial resolutions.
Remote Sensing, 14(22): 5759.
[48] Liu R, Yang X*,Xu C, Wei L, Zeng X (2022) Comparative study of convolutional
neural network and conventional machine learning methods for landslide
susceptibility mapping. Remote Sensing, 14(2): 321.
[49] Chen Y, He X*,Xu C, Huang Y, Zhang P, Luo Z, Zhan T (2022) Development characteristics
and causes of a fatal landslide occurred in Shuicheng, Guizhou Province,
China. ISPRS International Journal of Geo-Information, 11(2): 119.
[50] Cui Y, Hu J, Zheng J*, Fu G,Xu C(2021) Susceptibility assessment
of landslides caused by snowmelt in a typical loess area in the Yining
County, Xinjiang, China. Quarterly Journal of Engineering Geology and
Hydrogeology, 55(1): qjegh2021-2024.
[51] Cui Y*, Jing J, Huang Q*, Yuan K,Xu C(2022) A data-driven model for
spatial shallow landslide probability of occurrence due to a typhoon in
Ningguo City, Anhui Province, China. Forests, 13(5): 732.
[52] Xu Q, Li W, Tang C, Fan X, Luo Y, Zhu
J, Xu C, Xing A, Zhuang Y, Towhata I (2022). Report on landslides triggered
by the 2008 Wenchuan Earthquake. Coseismic Landslides Phenomena, Long-Term
Effects and Mitigation. I. Towhata, G. Wang, Q. Xu and C. Massey, Springer
Nature: 1-40.
(2021年)
[53] Xu
C*,
Xu X, Huang Y (2021) Preface to the special issue on geo-disasters. Journal
of Earth Science, 32(5): 1053-1055.
[54] Xu
C*,
Xu X (2021). A Panoramic View of the Landslides Triggered by the May 12th,
2008 Mw 7.9 Earthquake in Wenchuan, China. Earthquake Geology and
Tectonophysics around Eastern Tibet and Taiwan. C.-H. Lo, X. Xu, W.-Y. Chang
and M. Ando, Springer, Singapore:25-41.
[55] Ma S,Xu C*, Shao X, Xu X, Liu A (2021) A large old landslide in
Sichuan Province, China: surface displacement monitoring and potential
instability assessment. Remote Sensing, 13(13): 2552. doi:10.3390/rs13132552
[56] Ma S, Shao X,Xu C*, He X, Zhang P (2021) MAT.TRIGRS (V1.0): A new open-source
tool for predicting spatiotemporal distribution of rainfall-induced
landslides. Natural Hazards Research, 1(4): 161-170.
[57] Cui Y, Hu J,Xu C*, Zheng J, Wei J (2021) A catastrophic natural disaster
chain of typhoon-rainstorm-landslide-barrier lake-flooding in Zhejiang
Province, China. Journal of Mountain Science, 18(8): 2108-2119.
[58] Qi W, Yang W, He X,Xu C*(2021) Detecting Chamoli
landslide precursors in the Southern Himalayas using remote sensing data.
Landslides, 18(10): 3449-3456.
[59] Qi W,Xu C*, Xu X (2021) AutoGluon: A revolutionary framework for
landslide hazard analysis. Natural Hazards Research, 1(3): 103-108.
[60] Zhang X, Peng X, Chen S, Li X, Zhou Z,
Dou Z, He X,Xu C*(2021) Rapid
prediction of strong ground motions from major earthquakes: An application in
the Wudu basin, Sichuan, China. Bulletin of the Seismological Society of
America, 111(5): 2635-2660.
[61] Cui F*, Chen X, Wu Q, Xu C, Li N, Wu
Na, Cui L (2021) Dynamic response of the Daguangbao landslide triggered by
the Wenchuan earthquake with a composite hypocenter. Geomatics, Natural
Hazards and Risk, 12(1): 2170-2193.
[62] He X,Xu C*, Qi W, Huang Y, Cheng J, Xu X, Yao Q, Lu Y, Dai B (2021)
Landslides triggered by the 2020 Qiaojia Mw 5.1 Earthquake, Yunnan, China:
Distribution, influence factors and tectonic significance. Journal of Earth
Science, 32(5): 1056-1068.
[63] Maharjan S, Gnyawali KR*, Tannant DD,Xu C, Lacroix P (2021) Rapid terrain
assessment for earthquake-triggered landslide susceptibility with
high-resolution DEM and critical acceleration. Frontiers in Earth Science,
9(Article 689303): 14 pages.
[64] Basharat M, Riaz MT, Jan MQ,Xu C, Riaz S (2021) A review of
landslides related to the 2005 Kashmir Earthquake: Implication and future
challenges. Natural Hazards, 108(1): 1-30. doi:10.1007/s11069-021-04688-8
[65] Cui Y, Bao P,Xu C*, Ma S, Zheng J, Fu G (2021) Landslides triggered by the 6
September 2018 Mw 6.6 Hokkaido, Japan: an updated inventory and retrospective
hazard assessment. Earth Science Informatics, 14(1): 247-258.
[66] Cui Y, Deng J, Hu W,Xu C, Ge H, Wei J, Zheng J (2021)
36Cl exposure dating of the Mahu Giant landslide (Sichuan Province, China).
Engineering Geology, 285: 106039.
[67] Duan Y, Di B, Ustin SL,Xu C, Xie Q, Wu S, Li J, Zhang R
(2021) Changes in ecosystem services in a montane landscape impacted by major
earthquakes: A case study in Wenchuan earthquake-affected area, China. Ecological
Indicators, 126(107683): 12 pages.
[68] Huang Y,Xu C*, Zhang X, Xue C, Wang S (2021) An updated database and
spatial distribution of landslides triggered by the Milin, Tibet Mw 6.4
Earthquake of 18 November 2017. Journal of Earth Science, 32(5): 1069-1078.
[69] Shao X,Xu C*,Ma S, Xu X, Shyu JBH, Zhou Q (2021) Calculation of
landslide occurrence probability in Taiwan region under different ground
motion conditions. Journal of Mountain Science, 18(4): 1003-1012.
[70] Xia G, Liu C,Xu C, Le T (2021) Dynamic analysis of the high-speed and
long-runout landslide movement process based on the discrete element method:
A case study of the Shuicheng Landslide in Guizhou, China. Advances in Civil
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[71] Xu X,Xu C(2021) Natural Hazards Research: An eternal subject of human
survival and development. Natural Hazards Research, 1(1): 1-3.
[72] Yao X, Qi S, Liu C, Guo S, Huang X,Xu C, Zheng B, Zhan Z, Zou Y (2021)
An empirical attenuation model of the peak ground acceleration (PGA) in the
near field of a strong earthquake. Natural Hazards, 105(1): 691-715.
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seismic response in complex site conditions: A new approach based on an
auxiliary-model method. Journal of Earth Science, 32(5): 1152-1165.
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scenario prediction of failure, movement and energy dissipation of a
potential landslide under a seismic loading. Bulletin of Engineering Geology
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Earthquake-Triggered Landslides. Treatise on Geomorphology, Reference Module
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using certainty factor, support vector machine, random forest, CF-SVM and
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learning framework for landslide mapping from images of different areas with
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of landslides triggered by the 2019 Ms 6.0 Changning, Sichuan, China Ms6.0
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Sichuan Province, China, using interferometric synthetic aperture radar
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of Asian Rock Mechanics Society, IOP Conf. Series: Earth and Environmental
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seismic landslides in large areas with complex environments based on deep
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[105] Shao X, Ma S,Xu C*, Xu X (2020) Effects of raster resolution on real
probability of landslides. Remote Sensing Applications: Society and
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non-slide/slide sample ratio on the occurrence probability of coseismic
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3 August 2014 Ludian (China) Mw 6.2 earthquake: An updated inventory and
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[214] 许冲.
2015. 2008年汶川地震前的中国大陆地震单体滑坡与边坡地震响应.科技导报, 33(1): 107-119.
[215] 许冲.
2015.利用同震滑坡分析2014年鲁甸地震震源性质与破裂过程.工程地质学报, 23(4): 755-759.
[216] 田颖颖,许冲*,徐锡伟,吴赛儿,陈剑. 2015. 2014年鲁甸Ms6.5地震震前与同震滑坡空间分布规律对比分析.地震地质, 37(1): 291-306.
[217] 沈玲玲,杨文涛,刘连友,许冲,王静璞. 2015.基于TRMM降雨数据的四川省地质灾害降雨阈值分析.灾害学, 30(2): 220-227.
[218] 黎艳,陈剑,许冲,李凌婧,姚鑫. 2015.基于AHP的半干旱区泥石流易发性评价:以金沙江上游奔子栏—昌波河段为例.现代地质, 29(4): 975-982.
[219] 刘丽娜,许冲*,陈剑. 2015.基于地貌信息熵与滑坡物源的芦山地震区泥石流危险性评价.地震地质, 37(3): 880-892.
[220] 谭锡斌,徐锡伟,李元希,袁仁茂,于贵华,许冲. 2015.龙门山中段中央断裂和前山断裂的晚新生代垂向活动性差异及其构造意义.地球物理学报, 58(1): 143-152.
[221] 龙维,陈剑,王鹏飞,许冲,刘辉,孙进忠. 2015.金沙江上游特米大型古滑坡的成因及古地震参数反分析.地震研究, 38(4): 568-575.
(2014年)
[222] Xu C. 2014. Do buried-rupture earthquakes
trigger less landslides than surface-rupture earthquakes for reverse faults?
Geomorphology, 216: 53-57.
[223] Xu C. 2014. A preliminary spatial
distribution analysis of landslides triggered by the 2010 Haiti earthquake.
Landslide Science for a Safer Geoenvironment, Proceedings of World Landslide
Forum 3, 2-6 June 2014, Beijing, 3: 183-190.
[224] Xu C, Shyu JBH, Xu X. 2014. Landslides
triggered by the 12 January 2010 Port-au-Prince, Haiti, Mw = 7.0 earthquake:
visual interpretation, inventory compiling, and spatial distribution
statistical analysis. Natural Hazards and Earth System Sciences, 14(7):
1789-1818.
[225] Xu C, Xu X. 2014. The spatial distribution
pattern of landslides triggered by the 20 April 2013 Lushan earthquake of
China and its implication to identification of the seismogenic fault. Chinese
Science Bulletin, 59(13): 1416-1424.
[226] Xu C, Xu X. 2014. Statistical analysis of
landslides caused by the Mw 6.9 Yushu, China, earthquake of April 14, 2010.
Natural Hazards, 72(2): 871-893.
[227] Xu C, Xu X, Gorum T, van Westen CJ, Fan
XM. 2014. Did the 2008 Wenchuan earthquake lead to a net volume loss?
Landslide Science for a Safer Geoenvironment, Proceedings of World Landslide
Forum 3, 2-6 June 2014, Beijing, 3: 191-196.
[228] Xu C, Xu X, Pourghasemi HR, Pradhan B,
Iqbal J. 2014. Volume, gravitational potential energy reduction, and regional
centroid position change in the wake of landslides triggered by the 14 April
2010 Yushu earthquake of China. Arabian Journal of Geosciences, 7(6):
2129-2138.
[229] Xu C, Xu X, Shyu JBH, Zheng W, Min W.
2014. Landslides triggered by the 22 July 2013 Minxian-Zhangxian, China, Mw
5.9 earthquake: Inventory compiling and spatial distribution analysis.
Journal of Asian Earth Sciences, 92: 125-142.
[230] Xu C, Xu X, Yao X, Dai F. 2014. Three
(nearly) complete inventories of landslides triggered by the May 12, 2008
Wenchuan Mw 7.9 earthquake of China and their spatial distribution
statistical analysis. Landslides, 11(3): 441-461.
[231] Gorum T, Korup O, van Westen CJ, van der Meijde M,Xu C, van der Meer FD. 2014. Why so few? Landslides triggered by
the 2002 Denali earthquake, Alaska. Quaternary Science Reviews, 95: 80-94.
[232] Wang M, Yang WT, Shi PJ,Xu C,
Liu LY. 2014. Diagnosis of vegetation recovery in mountainous regions after
the Wenchuan Earthquake. IEEE Journal of Selected Topics in Applied Earth
Observations and Remote Sensing, 7(7): 3029-3037.
[233] Wang PF, Chen J, Dai FC, Long W,Xu
C, Sun JM, Cui ZJ. 2014. Chronology of relict lake deposits around the
Suwalong paleolandslide in the upper Jinsha River, SE Tibetan Plateau:
implications to Holocene tectonic perturbations. Geomorphology, 217: 193-203.
[234] Xiao JZ, Dai FC, Wei YQ, Min H,Xu
C, Tu XB, Wang ML. 2014. Cracking mechanism of secondary lining for a
shallow and asymmetrically-loaded tunnel in loose deposits. Tunnelling and
Underground Space Technology, 43: 232-240.
[235] 许冲.
2014. 2008年汶川地震前的中国大陆地震滑坡研究.科技导报, 32(16): 63-77.
[236] 许冲,徐锡伟. 2014. 21世纪初几次大地震事件触发滑坡基础数据建设.地震地质, 36(1): 90-104.
[237] 许冲,徐锡伟. 2014. 2013年芦山地震滑坡空间分布样式对盲逆断层构造的反映.科学通报, 59(11): 979-986.
[238] 许冲,徐锡伟,沈玲玲,窦帅,吴赛儿,田颖颖,李西. 2014. 2014年鲁甸Ms6.5地震触发滑坡编录及其对一些地震参数的指示.地震地质, 36(4): 1186-1203.
[239] 肖建章,戴福初,闵弘,许冲,涂新斌,王小东. 2014.松散堆积体围岩隧道施工方案对比分析.沈阳工业大学学报, 36(1): 106-113.
[240] 徐锡伟,程佳,许冲,李西,于贵华,陈桂华,谭锡斌,吴熙彦. 2014.青藏高原块体运动模型与地震活动主体地区讨论:鲁甸和景谷地震的启示.地震地质, 36(4): 1116-1134.
[241] 刘丽娜,许冲,徐锡伟,陈剑. 2014. GIS支持下基于AHP方法的2013年芦山地震区滑坡危险性评价.灾害学, 29(4): 183-191.
[242] 刘丽娜,许冲,陈剑. 2014. GIS支持下基于CF方法的2013年芦山地震滑坡因子敏感性分析.工程地质学报, 22(6): 1176-1186.
[243] 卢永兴,肖建章,许冲,谢启智,袁华. 2014.蓄水与施工作用下滑坡变形机制与稳定性分析.工程地质学报, 22(3): 386-395.
(2013年)
[244] Xu C. 2013. Assessment of
earthquake-triggered landslide susceptibility based on expert knowledge and
information value methods: A case study of the 20 April 2013 Lushan, China
Mw6.6 earthquake. Disaster Advances, 6(13): 119-130.
[245] Xu C(2013). Correlations of
earthquake-triggered landslides volume and seismogenic fault: A case study of
the 12 May 2008 Wenchuan earthquake, China. International Symposium & 9th
Asian Regional Conference of IAEG, Global View of Engineering Geology and the
Environment. Taylor & Francis Group, London, ISBN 978-1-138-00078-0.
Beijing: 93-98.
[246] Xu C(2013). Earthquake-triggered landslide
susceptibility mapping in the 2010 Yushu, China earthquake struck area using
artificial neural network model. International Symposium & 9th Asian
Regional Conference of IAEG, Global View of Engineering Geology and the
Environment. Taylor & Francis Group, London, ISBN 978-1-138-00078-0.
Beijing: 217-223.
[247] Xu C. 2013. Preliminary study on
landslides triggered by the April 20, 2013 Lushan, Mw 6.6 earthquake of
China. Acta Geologica Sinica (English Edition), 87(S): 402-402.
[248] Xu C, Xu X. 2013. Controlling parameter
analyses and hazard mapping for earthquake-triggered landslides: an example
from a square region in Beichuan County, Sichuan Province, China. Arabian
Journal of Geosciences, 6(10): 3827-3839.
[249] Xu C, Xu X, Yao Q, Wang Y. 2013. GIS-based
bivariate statistical modelling for earthquake-triggered landslides
susceptibility mapping related to the 2008 Wenchuan earthquake, China.
Quarterly Journal of Engineering Geology and Hydrogeology, 46(2): 221-236.
[250] Xu C, Xu X, Yu G. 2013. Landslides
triggered by slipping-fault-generated earthquake on a plateau: an example of
the 14 April 2010, Ms 7.1, Yushu, China earthquake. Landslides, 10(4):
421-431.
[251] Xu C, Xu X, Zhou B, Yu G. 2013. Revisions
of the M 8.0 Wenchuan earthquake seismic intensity map based on co-seismic landslide
abundance. Natural Hazards, 69(3): 1459-1476.
[252] Xu C, Xu XW, Dai FC, Wu ZD, He HL, Wu XY,
Xu SN, Shi F. 2013. Application of an incomplete landslide inventory,
logistic regression model and its validation for landslide susceptibility
mapping related to the May 12, 2008 Wenchuan earthquake of China. Natural
Hazards, 68(2): 883-900.
[253] Pourghasemi HR, Jirandeh AG, Pradhan B,Xu C, Gokceoglu C. 2013. Landslide susceptibility mapping using
support vector machine and GIS at the Golestan Province, Iran. Journal of
Earth System Science, 122(2): 349-369.
[254] Xu XW, Wen XZ, Han ZJ, Chen GH, Li CY, Zheng WJ, Zhang SM, Ren ZK,Xu C, Tan XB, Wei ZY, Wang MM, Ren
JJ, He ZT, Liang MJ. 2013. Lushan Ms 7.0 earthquake: A blind reserve-fault
event. Chinese Science Bulletin, 58(28-29): 3437-3443.
[255] Yao Q, Xu X, Xing H,Xu C,
Wang X. 2013. Decomposition and evolution of intracontinental strike-slip
faults in eastern Tibetan Plateau. Acta Geologica Sinica (English Edition),
87(2): 304-317.
[256] Yuan RM, Deng QH, Cunningham D,Xu
C, Xu XW, Chang CP. 2013. Density distribution of landslides triggered by
the 2008 Wenchuan earthquake and their relationships to peak ground
acceleration. Bulletin of the Seismological Society of America, 103(4):
2344-2355.
[257] 许冲. 2013. 2010年海地太子港地震触发滑坡危险性区划和合理性检验.科技导报, 31(12): 42-47.
[258] 许冲. 2013. 2013年芦山Ms7.0级地震滑坡易发性快速评价方法.科技导报, 31(28/29): 15-23.
[259] 许冲. 2013.基于最大似然法的地震滑坡信息自动提取及其可靠性检验.中国地质灾害与防治学报, 24(3): 19-25.
[260] 许冲. 2013.实际滑坡是滑坡危险性评价结果合理性检验最好的标准.工程地质学报, 21(6): 908-911.
[261] 许冲,肖建章. 2013. 2013年芦山地震滑坡空间分布分析——以太平镇东北方向的一个典型矩形区为例.地震地质, 35(2): 436-451.
[262] 许冲,徐锡伟. 2013. 2008年汶川地震导致的斜坡物质响应率及其空间分布规律分析.岩石力学与工程学报, 32(S2): 3888-3908.
[263] 许冲,徐锡伟. 2013.玉树地震滑坡体积、重力势能降与造成的区域质心改变定量研究.科技导报, 31(2): 22-29.
[264] 许冲,徐锡伟. 2013.地震滑坡编目图误差分析.地质论评, 59(6): 1177-1188.
[265] 许冲,徐锡伟,于贵华. 2013.基于证据权方法的玉树地震滑坡危险性评价.地震地质, 35(1): 151-164.
[266] 许冲,徐锡伟,吴熙彦,戴福初,姚鑫,姚琪. 2013. 2008年汶川地震滑坡详细编目及其空间分布规律分析.工程地质学报, 21(1): 25-44.
[267] 许冲,徐锡伟,郑文俊. 2013. 2013年7月22日岷县漳县Ms6.6级地震滑坡编录与空间分布规律分析.工程地质学报, 21(5): 736-749.
[268] 许冲,徐锡伟,郑文俊,魏占玉,谭锡斌,韩竹军,李传友,梁明剑,李志强,王虎,王明明,任俊杰,张世民,何仲太. 2013. 2013年四川省芦山“4.20”7.0级强烈地震触发滑坡.地震地质, 35(3): 641-660.
[269] 许冲,徐锡伟,郑文俊,闵伟,任治坤,李志强. 2013. 2013年甘肃岷县漳县6.6级地震触发滑坡及其构造分析.地震地质, 35(3): 616-626.
[270] 许冲,戴福初,徐素宁,徐锡伟,何宏林,吴熙彦,石峰. 2013.基于逻辑回归模型的汶川地震滑坡危险性评价与检验.水文地质工程地质, 40(3): 98-104.
[271] 田颖颖,许冲,徐锡伟,陈剑. 2013. 2013年岷县漳县Ms6.6地震滑坡特征参数分析.地震工程学报, 35(4): 761-767.
[272] 李传友,徐锡伟,甘卫军,闻学泽,郑文俊,魏占玉,许冲,谭锡斌,陈桂华,梁明剑,李新男. 2013.四川省芦山Ms7.0地震发震构造分析.地震地质, 35(3): 671-683.
[273] 肖建章,戴福初,闵弘,许冲,涂新斌,王明龙. 2013.浅埋偏压堆积体围岩隧道二次衬砌开裂机理分析.现代隧道技术, 50(6): 101-109.
[274] 徐锡伟,闻学泽,韩竹军,陈桂华,李传友,郑文俊,张世民,任治坤,许冲,谭锡斌,魏占玉,王明明,任俊杰,何仲,梁明剑. 2013.四川芦山7.0级强震:一次典型的盲逆断层型地震.科学通报, 58(20): 1887-1893.
[275] 廖彬秀,戴福初,闵弘,王明龙,许冲. 2013.降雨条件下边坡水文响应及其变形过程分析——以深圳大龙山边坡为例.水文地质工程地质, 40(4): 63-69.
[276] 谭锡斌,李元希,徐锡伟,陈玟禹,许冲,于贵华. 2013.低温热年代学数据对龙门山推覆构造带南段新生代构造活动的约束.地震地质, 35(3): 506-517.
[277] 郑文俊,袁道阳,何文贵,闵伟,任治坤,刘兴旺,王爱国,许冲,葛伟鹏,李峰. 2013.甘肃东南地区构造活动与2013年岷县—漳县Ms6.6级地震孕震机制.地球物理学报, 56(12): 4058-4071.
[278] 郑文俊,闵伟,何文贵,任治坤,刘兴旺,王爱国,许冲,李峰. 2013. 2013年甘肃岷县漳县6.6级地震震害分布特征及发震构造分析.地震地质, 35(3): 604-615.
(2012年)
[279] Xu C, Dai F, Xu X, Lee YH. 2012. GIS-based
support vector machine modeling of earthquake-triggered landslide
susceptibility in the Jianjiang River watershed, China. Geomorphology,
145-146: 70-80.
[280] Xu C, Xu X. 2012. Comment on “Spatial
distribution analysis of landslides triggered by 2008.5. 12 Wenchuan
Earthquake, China” by Shengwen Qi, Qiang Xu, Hengxing Lan, Bing Zhang,
Jianyou Liu [Engineering Geology 116 (2010) 95–108]. Engineering Geology,
133-134: 40-42.
[281] Xu C, Xu X, Dai F, Saraf AK. 2012.
Comparison of different models for susceptibility mapping of earthquake
triggered landslides related with the 2008 Wenchuan earthquake in China.
Computers & Geosciences, 46: 317-329.
[282] Xu C, Xu X, Dai F, Xiao J, Tan X, Yuan R.
2012. Landslide hazard mapping using GIS and weight of evidence model in
Qingshui River watershed of 2008 Wenchuan earthquake struck region. Journal
of Earth Science, 23(1): 97-120.
[283] Xu C, Xu X, Lee YH, Tan X, Yu G, Dai F.
2012. The 2010 Yushu earthquake triggered landslide hazard mapping using GIS
and weight of evidence modeling. Environmental Earth Sciences, 66(6):
1603-1616.
[284] Xu C, Xu X, Yu G. 2012. Earthquake
triggered landslide hazard mapping and validation related with the 2010
Port-au-Prince, Haiti earthquake. Disaster Advances, 5(4): 1297-1304.
[285] Tan XB, Yuan RM, Xu XW, Chen GH, Klinger Y, Chang CP, Ren JJ,Xu C, Li K. 2012. Complex surface
rupturing and related formation mechanisms in the Xiaoyudong area for the
2008 Mw 7.9 Wenchuan Earthquake, China. Journal of Asian Earth Sciences, 58:
132-142.
[286] 许冲.
2012.汶川地震滑坡分布规律与危险性评价.岩石力学与工程学报, 31(2): 432-432.
[287] 许冲.
2012.汶川地震滑坡详细编录及其与全球其他地震滑坡事件对比.科技导报, 30(25): 18-26.
[288] 许冲,徐锡伟. 2012.走滑断裂型地震诱发的滑坡在断裂两盘的空间分布差异.地质通报, 31(4): 532-540.
[289] 许冲,徐锡伟. 2012.俯冲带地区压扭断裂型地震触发滑坡及其剥蚀厚度空间分布规律分析.工程地质学报, 20(5): 732-744.
[290] 许冲,徐锡伟. 2012.基于GIS与ANN模型的地震滑坡易发性区划.地质科技情报, 31(3): 116-121.
[291] 许冲,徐锡伟. 2012.基于不同核函数的2010年玉树地震滑坡空间预测模型研究.地球物理学报, 55(9): 2994-3005.
[292] 许冲,徐锡伟. 2012.逻辑回归模型在玉树地震滑坡危险性评价中的应用与检验.工程地质学报, 20(3): 326-333.
[293] 许冲,徐锡伟,于贵华. 2012.玉树地震滑坡分布调查及其特征与形成机制.地震地质, 34(1): 47-62.
[294] 许冲,徐锡伟,于贵华,吴熙彦. 2012.玉树地震滑坡影响因子敏感性分析.科技导报, 30(1): 18-24.
[295] Xu C, Xu X-W. 2012. Spatial prediction
models for seismic landslides based on support vector machine and varied
kernel functions: A case study of the 14 April 2010 Yushu earthquake in
China. Chinese Journal of Geophysics, 55(6): 666-679.
[296] 赵洲,侯恩科,王建智,邓念东,许冲. 2012.县域滑坡灾害风险管理信息系统研发与应用:以陕西省宁强县为例.工程地质学报, 20(2): 170-182.
(2011年)
[297] Dai FC, Tu XB,Xu C, Gong QM,
Yao X. 2011. Rock avalanches triggered by oblique-thrusting during the 12 May
2008 Ms 8.0 Wenchuan earthquake, China. Geomorphology, 132(3-4): 300-318.
[298] Dai FC,Xu C, Yao X, Xu L, Tu
XB, Gong QM. 2011. Spatial distribution of landslides triggered by the 2008
Ms 8.0 Wenchuan earthquake, China. Journal of Asian Earth Sciences, 40(4):
883-895.
[299] 许冲,徐锡伟,戴福初,王彦颖. 2011. 2010年4月14日玉树地震滑坡空间分布与控制变量分析.工程地质学报, 19(4): 505-510.
[300] 许冲,戴福初,肖建章. 2011. “5.12”汶川地震诱发滑坡特征参数统计分析.自然灾害学报, 20(4): 147-153.
[301] 许冲,戴福初,徐锡伟. 2011.基于GIS平台与证据权的地震滑坡易发性评价.地球科学:中国地质大学学报, 36(6): 1155-1164.
[302] 曹琰波,戴福初,许冲,涂新斌,闵弘,崔芳鹏. 2011.唐家山滑坡变形运动机制的离散元模拟.岩石力学与工程学报, 30(S1): 2878-2887.
[303] 陈剑,崔之久,戴福初,许冲. 2011.金沙江奔子栏-达日河段大型泥石流堆积扇的成因机制.山地学报, 29(3): 312-319.
(2010年)
[304] 许冲,戴福初,姚鑫,赵洲,肖建章. 2010.基于GIS与确定性系数分析方法的汶川地震滑坡易发性评价.工程地质学报, 18(1): 15-26.
[305] 许冲,戴福初,姚鑫,陈剑,涂新斌,肖建章,孙瑜. 2010.汶川地震滑坡在两个典型区域内的分布研究.中国科学院研究生院学报, 27(5): 621-631.
[306] 许冲,戴福初,姚鑫,陈剑,涂新斌,曹琰波,肖建章. 2010.基于GIS的汶川地震滑坡灾害影响因子确定性系数分析.岩石力学与工程学报, 29(S1): 2972-2981.
[307] 许冲,戴福初,徐锡伟. 2010.汶川地震滑坡灾害研究综述.地质论评, 56(6): 860-874.
(2009年)
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