地质工程与测绘学院

近几年发表学术论文（部分）

（1）Chen, W., Peng, J., Hong, H., Shahabi, H., Pradhan, B., Liu, J., . . . Duan, Z. (2018). Landslide susceptibility modelling using GIS-based machine learning techniques for Chongren County, Jiangxi Province, China. Science of the Total Environment, 626, 1121-1135..2018.01.124

（2）Huang, Q., Jia, X., Peng, J., Liu, Y., & Wang, T. (2019). Seismic response of loess-mudstone slope with bedding fault zone. Soil Dynamics and Earthquake Engineering, 123, 371-380.

（3）Huo, A., Peng, J., Chen, X., Deng, L., Wang, G., & Cheng, Y. (2016). Groundwater storage and depletion trends in the Loess areas of China. Environmental Earth Sciences, 75(16).

（4）Leng, Y., Peng, J., Wang, Q., Meng, Z., & Huang, W. (2018). A fluidized landslide occurred in the Loess Plateau: A study on loess landslide in South Jingyang tableland. Engineering Geology, 236, 129-136.

（5）Lian, B., Peng, J., Zhan, H., & Wang, X. (2019). Mechanical response of root-reinforced loess with various water contents. Soil & Tillage Research, 193, 85-94.

（6）Liu, N., Lu, Q., Li, J., Peng, J., Fan, W., & Liu, W. (2019). Physical Modeling and Numerical Simulation of the Seismic Responses of Metro Tunnel near Active Ground Fissures. Complexity, 2019.

（7）Lu, Q., Li, L., Peng, J., Chen, S., Hu, P., & Wu, H. (2015). A combined element model with hinged connection for simulating inhomogeneous axial deformation of subgrade soil in ground fissure zone. China Railway Science, 36(1), 11-17.

（8）Lu, Q., Qiao, J., Peng, J., Liu, Z., Liu, C., Tian, L., & Zhao, J. (2019). A typical Earth fissure resulting from loess collapse on the loess plateau in the Weihe Basin, China. Engineering Geology, 259.

（9）Lu, Q.-z., Chen, S.-f., Peng, J.-b., Meng, Z.-j., & Hu, P. (2015). Stress-strain Features and Deformation Failure Mechanisms of Fissured Loess Under Triaxial Compression. China Journal of Highway and Transport, 28(1), 8-16.

（10）Lu, Q.-z., Wu, H.-l., Peng, J.-b., Hu, P., & Liu, Y. (2015). Compression characteristic and control measure of subgrade soil in ground fissure zone. China Journal of Highway and Transport, 28(7), 10-17.

（11）Ma, P., Peng, J., Wang, Q., Duan, Z., Meng, Z., & Jianqi, Z. (2019). Loess landslides on the South Jingyang Platform in Xi'an, China. Quarterly Journal of Engineering Geology and Hydrogeology, 52(4), 547-556.

（12）Ma, P., Peng, J., Wang, Q., Zhuang, J., & Zhang, F. (2019). The mechanisms of a loess landslide triggered by diversion-based irrigation: a case study of the South Jingyang Platform, China. Bulletin of Engineering Geology and the Environment, 78(7), 4945-4963.

（13）Peng, J., Fan, Z., Liu, C., Huang, Q., Liu, J., Ren, H., . . . Meng, Z. (2019). EXPERIMENTAL ANALYSIS OF A HIGH-SPEED-RAILWAY EMBANKMENT INTERSECTING STEEP GROUND FISSURES AT DIFFERENT ANGLES. Acta Geotechnica Slovenica, 16(1), 13-29.

（14）Peng, J., Fan, Z., Wu, D., Huang, Q., Wang, Q., Zhuang, J., & Che, W. (2019). Landslides triggered by excavation in the loess plateau of China: A case study of Middle Pleistocene loess slopes. Journal of Asian Earth Sciences, 171, 246-258.

（15）Peng, J., Fan, Z., Wu, D., Zhuang, J., Dai, F., Chen, W., & Zhao, C. (2015). Heavy rainfall triggered loess-mudstone landslide and subsequent debris flow in Tianshui, China. Engineering Geology, 186, 79-90.

（16）Peng, J., He, K., Tong, X., Huang, Q., & Liu, C. (2017). Failure Mechanism of an Underground Metro Tunnel Intersecting Steep Ground Fissure at Low Angle. International Journal of Geomechanics, 17(5).

（17）Peng, J., Huo, A., Cheng, Y., Dang, J., Wei, H., Wang, X., & Li, C. (2017). Submersion simulation in a typical debris flow watershed of Jianzhuangchuan catchment, Loess Plateau. Environmental Earth Sciences, 76(13).

（18）Peng, J., Leng, Y., Zhu, X., Wu, D., & Tong, X. (2016). Development of a loess-mudstone landslide in a fault fracture zone. Environmental Earth Sciences, 75(8).

（19）Peng, J., Ma, P., Wang, Q., Zhu, X., Zhang, F., Tong, X., & Huang, W. (2018). Interaction between landsliding materials and the underlying erodible bed in a loess flowslide. Engineering Geology, 234, 38-49.

（20）Peng, J., Meng, L., Lu, Q., Deng, Y., & Meng, Z. (2018). Development characteristics and mechanisms of the Taigu-Qixian earth fissure group in the Taiyuan basin, China. Environmental Earth Sciences, 77(11).

（21）Peng, J., Qi, S., Williams, A., & Dijkstra, T. A. (2018). Preface to the special issue on Loess engineering properties and loess geohazards. Engineering Geology, 236, 1-3.

（22）Peng, J., Qiao, J., Leng, Y., Wang, F., & Xue, S. (2016). Distribution and mechanism of the ground fissures in Wei River Basin, the origin of the Silk Road. Environmental Earth Sciences, 75(8).

（23）Peng, J., Qu, W., Ren, J., Zhang, Q., & Wang, F. (2018). Geological Factors for the Formation of Xi'an Ground Fractures. Journal of Earth Science, 29(2), 468-478.

（24）Peng, J., Sun, P., Igwe, O., & Li, X. a. (2018). Loess caves, a special kind of geo-hazard on loess plateau, northwestern China. Engineering Geology, 236, 79-88.

（25）Peng, J., Tong, X., Wang, S., & Ma, P. (2018). Three-dimensional geological structures and sliding factors and modes of loess landslides. Environmental Earth Sciences, 77(19).

（26）Peng, J., Wang, F., Cheng, Y., & Lu, Q. (2018). Characteristics and mechanism of Sanyuan ground fissures in the Weihe Basin, China. Engineering Geology, 247, 48-57.

（27）Peng, J., Wang, G., Wang, Q., & Zhang, F. (2017). Shear wave velocity imaging of landslide debris deposited on an erodible bed and possible movement mechanism for a loess landslide in Jingyang, Xi'an, China. Landslides, 14(4), 1503-1512.

（28）Peng, J., Wang, S., Wang, Q., Zhuang, J., Huang, W., Zhu, X., . . . Ma, P. (2019). Distribution and genetic types of loess landslides in China. Journal of Asian Earth Sciences, 170, 329-350.

（29）Peng, J., Xu, J., Ma, R., & Wang, F. (2016). Characteristics and mechanism of the Longyao ground fissure on North China Plain, China. Engineering Geology, 214, 136-146.

（30）Peng, J., Zhang, F., & Wang, G. (2017). Rapid loess flow slides in Heifangtai terrace, Gansu, China. Quarterly Journal of Engineering Geology and Hydrogeology, 50(2), 106-110.

（31）Peng, J., Zhang, F., & Wang, G. (2017). Rapid loess flow slides in Heifangtai terrace, Gansu, China (vol 50, pg 106, 2017). Quarterly Journal of Engineering Geology and Hydrogeology, 50(4), 478-478.

（32）Peng, J., Zhuang, J., Wang, G., Dai, F., Zhang, F., Huang, W., & Xu, Q. (2018). Liquefaction of loess landslides as a consequence of irrigation. Quarterly Journal of Engineering Geology and Hydrogeology, 51(3), 330-337.

（33）Qiao, J., Peng, J., Deng, Y., Leng, Y., & Meng, Z. (2018). Earth fissures in Qinglong Graben in Yuncheng Basin, China. Journal of Earth System Science, 127(1).

（34）Sun, G., & Peng, J. (2017). The lengthy high-stress consolidation test research on silty clay in Xi'an. In Y. H. Kim (Ed.), Proceedings of the 2017 6th International Conference on Energy and Environmental Protection (Vol. 143, pp. 1301-1304).

（35）Sun, G., Peng, J., & Sun, X. (2015). The model test about silty clay's deformation as water pressure decreasing. In G. Zhang & M. Lee (Eds.), Proceedings of the 2015 International Conference on Materials, Environmental and Biological Engineering (Vol. 10, pp. 1086-1089).

（36）Sun, P., Peng, J., Chen, L., Lu, Q., & Igwe, O. (2016). An experimental study of the mechanical characteristics of fractured loess in western China. Bulletin of Engineering Geology and the Environment, 75(4), 1639-1647. doi:10.1007/s10064-015-0793-y

（37）Sun, P., Peng, J., Wu, S., & Lu, Q. (2015). An experimental study on mechanical properties of fractured loess. Journal of Central South University (Science and Technology), 46(6), 2188-2195.

（38）Tang, D., & Peng, J. (2015). Statistical analysis of excavation model of the loess landslide developmental characteristics. Applied Mechanics and Materials, 744-746, 601-605.

（39）Wang, F., Peng, J., Lu, Q., Cheng, Y., Meng, Z., & Qiao, J. (2019). Mechanism of Fuping ground fissure in the Weihe Basin of northwest China: fault and rainfall. Environmental Earth Sciences, 78(14).

（40）Wang, F., Peng, J., Meng, Z., Qiao, J., Wen, H., Ma, P., . . . Zhao, J. (2019). The origin and impact of the Shizhuang ground fissure, Yingxian area, Datong Basin, China. Engineering Geology, 261.

（41）.Wang, S., Peng, J., Zhuang, J., Kang, C., & Jia, Z. (2019). Underlying mechanisms of the geohazards of macro Loess discontinuities on the Chinese Loess Plateau. Engineering Geology, 263.

（42）Xu, J., Peng, J., & An, H. (2019). Experimental study on Su-Xi-Chang earth fissures induced by repeated groundwater pumping and impounding. Geomatics Natural Hazards & Risk, 10(1), 2051-2068.

（43）Xu, J., Peng, J., An, H., Wang, F., Sun, H., Hu, H., & Yang, B. (2019). Paleochannel-controlled earth fissures in Darning, North China Plain and their implication for underground paleogeomorphology. Geomorphology, 327, 523-532.

（44）Xu, J., Peng, J., Deng, Y., He, H., Meng, L., & Wang, F. (2018). Classification, grading criteria and quantitative expression of earth fissures: a case study in Daming Area, North China Plain. Geomatics Natural Hazards & Risk, 9(1), 862-880.

（45）Xu, J., Peng, J., Deng, Y., & Wang, F. (2019). Development characteristics and formation analysis of Baixiang earth fissure on North China plain. Bulletin of Engineering Geology and the Environment, 78(5), 3085-3094.

（46）Yan, R.-X., Peng, J.-B., Huang, Q.-B., Chen, L.-J., Kang, C.-Y., & Shen, Y.-J. (2019). Triggering Influence of Seasonal Agricultural Irrigation on Shallow Loess Landslides on the South Jingyang Plateau, China. Water, 11(7).

（47）Yang, C., Lu, Z., Zhang, Q., Zhao, C., Peng, J., & Ji, L. (2018). Deformation at longyao ground fissure and its surroundings, north China plain, revealed by ALOS PALSAR PS-InSAR. International Journal of Applied Earth Observation and Geoinformation, 67, 1-9.

（48）Zang, M., Peng, J., & Qi, S. (2019). Earth fissures developed within collapsible loess area caused by groundwater uplift in Weihe watershed, northwestern China. Journal of Asian Earth Sciences, 173, 364-373.

（49）Zhang, F., Kong, R., & Peng, J. (2018). Effects of heating on compositional, structural, and physicochemical properties of loess under laboratory conditions. Applied Clay Science, 152, 259-266.

（50）Zhen-jiang, M., Jian-bing, P., Qiang-bing, H., Va-hong, D., Lin-hao, Z., & Yan, X. (2017). Influence of ground fissure activity on subway tunnel in third-kind surveying site. Journal of Traffic and Transportation Engineering, 17(2), 41-51.

（51）Zhongjie, F., Kulatilake, P. H. S. W., Jianbing, P., Wenyue, C., Yazhe, L., & Zhenjiang, M. (2016). In-flight excavation of a loess slope in a centrifuge model test. Geotechnical and Geological Engineering, 34(5), 1577-1591.

（52）Zhu, X., Peng, J., Jiang, C., & Guo, W. (2019). A Preliminary Study of the Failure Modes and Process of Landslide Dams Due to Upstream Flow. Water, 11(6).

（53）Zhu, X.-h., Cui, Y.-f., Peng, J.-b., Jiang, C., & Guo, W.-l. (2019). Erosion and transport mechanisms of mine waste along gullies. Journal of Mountain Science, 16(2), 402-413.

（54）Zhu, X.-h., Peng, J.-b., Jiang, C., & Guo, W.-l. (2019). Formation conditions of landslide dams triggered by incision of mine waste accumulations. Journal of Mountain Science, 16(1), 108-121.

（55）Zhuang, J., Peng, J., Iqbal, J., Liu, T., Liu, N., Li, Y., & Ma, P. (2015). Identification of landslide spatial distribution and susceptibility assessment in relation to topography in the Xi'an Region, Shaanxi Province, China. Frontiers of Earth Science, 9(3), 449-462.

（56）Zhuang, J., Peng, J., Wang, G., Iqbal, J., Wang, Y., Li, W., . . . Zhu, X. (2017). Prediction of rainfall-induced shallow landslides in the Loess Plateau, Yan'an, China, using the TRIGRS model. Earth Surface Processes and Landforms, 42(6), 915-927. doi:10.1002/esp.4050

（57）Zhuang, J., Peng, J., Wang, G., Javed, I., Wang, Y., & Li, W. (2018). Distribution and characteristics of landslide in Loess Plateau: A case study in Shaanxi province. Engineering Geology, 236, 89-96.

（58）Zhuang, J., Peng, J., Xu, C., Li, Z., Densmore, A., Milledge, D., . . . Cui, Y. (2018). Distribution and characteristics of loess landslides triggered by the 1920 Haiyuan Earthquake, Northwest of China. Geomorphology, 314, 1-12.

（59）Zhuang, J., Peng, J., Xu, Y., Xu, Q., Zhu, X., & Li, W. (2016). Assessment and mapping of slope stability based on slope units: A case study in Yan'an, China. Journal of Earth System Science, 125(7), 1439-1450.

（60）Zhuang, J., Peng, J., Zhu, X., & Huang, W. (2019). Scenario-Based Risk Assessment of Earthquake Disaster Using Slope Displacement, PGA, and Population Density in the Guyuan Region, China. Isprs International Journal of Geo-Information, 8(2).

（61）Zhuang, J., Peng, J., Zhu, X., Li, W., Ma, P., & Liu, T. (2016). Spatial distribution and susceptibility zoning of geohazards along the Silk Road, Xian-Lanzhou. Environmental Earth Sciences, 75(8).

(62) Peng Jianbing(*)，Leng Yanqiu， Development of a loess-mudstone landslide in afault fracture zone，ENVIRONMENTAL EARTH SCIENCES，2016.01.01，75（8）：1~11

(63) 彭建兵(*) ，林鸿州，王启耀，庄建琦，成玉祥，朱兴华，黄土地质灾害研究中的关键问题与创新思路，工程地质学报，2014.8.15，（04）：684~691

(64) 彭建兵(*) ，李喜安，范文，陈志新，苏生瑞，宋彦辉，卢全中，邓亚虹，陈立伟，孙萍，黄土高原地区黄土洞穴的分类及发育规律，地学前缘，2007.11.15，（06）

(65) Jianqi Zhuang ，Jianbing Peng(*)Identification of landslide spatial distribution and susceptibility assessment in relation to topography in the Xi’an Region, Shaanxi Province, China，Front. Earth Sci.，015.01.01，9（3）：449~462

(66) Jianqi Zhuang，Jianbing Peng (*)Probability prediction model for landslide occurrences in Xi’an, Shaanxi Province, China，Journal of Mountain Science，2014.01.01，11（2）：345~359

(67) Zhuang, Jian-qi，Peng, Jian-bing(*)A coupled slope cuttinga prolonged rainfall-induced loess landslide: a 17 October 2011 case study，Bulletin of Engineering Geology and the Environment，2014.01.01，73（4）：997~1011

(68) Yan Lv，Jianbing Peng(*) ，Genlong WangCharacteristics and genetic mechanism of the Cuihua Rock Avalanche triggered by a paleo-earthquake in northwest China，Engineering Geology，2014.11.19，182：88~96

(69) Bai Chaoying，Peng Jianbing(*) ，S. Grenhalgh，3-D P-wave velocity structure of the crust beneath the Loess Plateau and surrounding regions of China，Tectonophysics，2008.9.10，460（11）：278~287

(70) Wu, Di，Jin, Long，Peng, Jianbing(*) ，Dong, Yuanhong，Liu, Zhiyun，The thermal budget evaluation of the two-phase closed thermosyphon embankment of the Qinghai-Tibet Highway in permafrost regions，Cold Regions Science and Technology，2014.7.01，103：115~122

(71) 李喜安，彭建兵(*)，陈志新，李滨，黄土地层地表径流下潜模式与地质灾害，工程地质学报，2007.8.15，（04）

(72) 孙萍，彭建兵(*) ，陈立伟，王志新,黄土拉张破裂特性试验研究岩土工程学报，2009.6.15，（06）

(73) 卢全中，彭建兵(*),黄土体结构面的发育特征及其灾害效应西安科技大学学报，2006.12.30，（04）

(74) 庄建琦，彭建兵(*),“9.17”灞桥灾难性黄土滑坡形成因素与运动模拟工程地质学报

(75) 庄建琦，彭建兵(*)，张利勇,不同降雨条件下黄土高原浅层滑坡危险性预测评价研究，吉林大学学报(地球科学版)

(76) 卢全中，彭建兵(*)，范文，孙刚臣,大尺寸裂隙性黄土的直剪试验公路2006.5.25，（05）

(77) 卢全中，彭建兵(*),黄土体工程地质的研究体系及若干问题探讨吉林大学学报(地球科学版)，2006.5.26，（03）

(78) 唐东旗 ，彭建兵(*),非饱和黄土基质吸力的滤纸法测试煤田地质与勘探2012.10.17，40（5）：37~41

(79) 卢全中，葛修润，彭建兵(*),三轴压缩条件下裂隙性黄土的破坏特征岩土力学，2009.12.15，30（12）：3689~3694

(80) 杨银科，彭建兵(*)，刘聪,滑坡年代学研究方法应用进展灾害学2015.01.01，（02）：133~137

(81) 卢全中，陈树峰，彭建兵(*),三轴压缩条件下裂隙性黄土应力－应变特性及变形破坏机制，中国公路学报，2015.1.01，28（1）：9~16

(82) 周保，彭建兵(*)，殷跃平，李小林，魏刚，马小强,黄河上游拉干峡——寺沟峡段特大型滑坡及其成因研究，地质论评，2014.01.01，（01）：138~144

著作

(1) 彭建兵，王启耀，门玉明，许强，庄建琦等，黄土高原滑坡灾害，科学出版社，2019.02.01

(2) 彭建兵，卢全中，黄强兵等，汾渭盆地地裂缝灾害，科学出版社，2017.01.01

(3) 彭建兵，张勤，黄强兵等，西安地裂缝灾害，科学出版社，2012.01.01

(4) 彭建兵，李庆春，陈志新等，黄土洞穴灾害，科学出版社，2008.01.01

(5) 彭建兵等，区域稳定动力学研究，科学出版社，2001.01.01