学术论文
[1] Ke Man, Xiaoli Liu*, Zhifei Song. Rock blasting vibration velocity and excavation damaged zone for the high-level radioactive waste geological disposal. Geomatics, Natural Hazards and Risk. 2021, 12(1): 2590-2606.
[2] Kumar N, Liu X*, Narayanasamydamodaran S, Pandey KK. A Systematic Review Comparing Urban Flood Management Practices in India to China’s Sponge City Program. Sustainability. 2021, 13(11):6346.
[3] Huan Sun, Xiaoli Liu*, Zhenni Ye, Enzhi Wang. Experimental investigation of the nonlinear evolution from pipe flow to fissure flow during carbonate rock failures. Bulletin of Engineering Geology and the Environment. 2021, 80:4459–4470.
[4] Chen Xu, Xiaoli Liu*, Enzhi Wang, Sijing Wang. Calibration of the Microparameters of Rock Specimens by Using Various Machine Learning Algorithms. International Journal of Geomechanics. 2021, 21(5): 04021060
[5] Danqing Song, Xiaoli Liu*, Jin Huang, Yufang Zhang, Jianmin Zhang, Benedict Nganteh Nkwenti. Seismic cumulative failure effects on a reservoir bank slope with a complex geological structure considering plastic deformation characteristics using shaking table tests. Engineering Geology. 2021, 286: 106085
[6] Chen Xu, Xiaoli Liu*, Enzhi Wang, Sijing Wang. Prediction of tunnel boring machine operating parameters using various machine learning algorithms. Tunnelling and Underground Space Technology. 2021, 109: 103699
[7] Danqing Song, Xiaoli Liu*, Bin Li, Jianmin Zhang, Juan Jose Volcan Bastos. Assessing the influence of a rapid water drawdown on the seismic response characteristics of a reservoir rock slope using time–frequency analysis. Acta Geotechnica. 2021, 16:1281–1302.
[8] Zhizeng Zhang, Yongtao Li, Weili Yang, Shunchuan Wu, Xiaoli Liu, Bing Zhang. Optimization of Measuring Points Layout around a Tunnel in the Transversely Isotropic Rock Mass. Shock and Vibration. 2021, 2021, 6643166
[9] O'Kelly B.C., El-Zein A., Liu X., Patel A., Fei X., Sharma S., Mohammad A., Goli V.S.N.S., Wang J.J., Li D., Shi Y., Xiao L., Kuntikana G., Shashank B.S., Sarris T.S., Rao B.H., Mohamed A.M.O., Paleologos E.K., Nezhad M.M. and Singh D.N., Microplastics in soils: an environmental geotechnics perspective. Environmental Geotechnics. 2021, https://doi.org/10.1680/jenge.20.00179
[10] Danqing Song, Xiaoli Liu, Zhuo Chen*, Jundong Chen, Jianhua Cai. Influence of Tunnel Excavation on the Stability of Bedded Rock Slope: A Case Study of the Mountainous Area in Southern Anhui, China. KSCE Journal of Civil Engineering. 2021, 25:114–123.
[11] Danqing Song, Xiaoli Liu*, Jin Huang & Jianmin Zhang. Energy-based analysis of seismic failure mechanism of a rock slope with discontinuities using Hilbert-Huang transform and marginal spectrum in the time-frequency domain. Landslides. 2021, 18:105–123.
[12] Yujie Zhu, Xiaoli Liu*, Enzhi Wang. Influence of impoundment gravity and pore pressure on reactivation of faults. Geomech. Geophys. Geo-energ. Geo-resour. 2020, 6:64
[13] Danqing Song, Xiaoli Liu*, Jin Huang & Jianmin Zhang. Characteristics of wave propagation through rock mass slopes with weak structural planes and their impacts on the seismic response characteristics of slopes: a case study in the middle reaches of Jinsha River. Bulletin of Engineering Geology and the Environment. 2020, 80(2), 1317-1334.
[14] Zhizeng Zhang, Xiaoli Liu*, Lijuan Cheng, Shunchuan Wu, Bing Zhang. A rheological constitutive model for damaged zone evolution of a tunnel considering strain hardening and softening. Geomech. Geophys. Geo-energ. Geo-resour. (2020) 6:56
[15] Guo-feng Han, Xiao-li Liu*, Jin Huang, Kumar Nawnit, Liang Sun. Alternative constitutive relation for the momentum transport of extended Navier-Stokes equations. Chinese Physics B. 2020, 29(12): 124701.
[16] Guofeng Han, Xiaoli Liu *, Jin Huang. Theoretical comparison of test performance of different pulse decay methods for unconventional cores. Energies. 2020, 13(17), 4557.
[17] Jin Huang, Xiaoli Liu*, Jian Zhao, Enzhi Wang, Sijing Wang. Propagation of Stress Waves Through Fully Saturated Rock Joint Under Undrained Conditions and Dynamic Response Characteristics of Filling Liquid. Rock mechanics and rock engineering. 2020, 53: 3637-3655.
[18] Guofeng Han, Xiaoli Liu*, Jin Huang, Kumar Nawnit, Liang Sun. Modified Boltzmann equation and extended Navier–Stokes equations. Physics of Fluids. 2020, 32: 022001.
[19] Sun H, Liu XL*, Zhang SG, Nawnit K. Experimental investigation of acoustic emission and infrared radiation thermography of dynamic fracturing process of hard-rock pillar in extremely steep and thick coal seams. Engineering Fracture Mechanics. 2020, 226:106845.
[20] Cun Hui, Fan Zhang, Zhizeng Zhang, Xiaoli Liu, Ran Hai1, John J. Myers. Research on the Compression Behavior of Steel Reinforced Concrete Columns With Built-in Steel Tubes. International Journal of Steel Structures. 2020, 20: 1319-1326.
[21] Jianbo Zhu, Tianqi Zhai, Zhiyi Liao, Shengqi Yang, Xiaoli Liu, Tao Zhou. Low‑Amplitude Wave Propagation and Attenuation Through Damaged Rock and a Classification Scheme for Rock Fracturing Degree. Rock Mechanics and Rock Engineering. 2020, 53: 3983-4000.
[22] Qiangling Yao, Chuanjin Tang, Ze Xia, Xiaoli Liu, Liu Zhu, Zhaohui Chong, Xindong Hui. Mechanisms of failure in coal samples from underground water reservoir. Engineering Geology. 2020, 267: 105494
[23] Liu XL*, Wang F, Nawnit K., Lv XF*, Wang SJ. Experimental study on debris flow initiation. Bulletin of Engineering Geology and the Environment. 2020, 79: 1565-1580
[24] Lv XF, Zhou HY*, Liu XL*, Song YM. Experimental study on the effect of basalt fiber on the shear behavior of cemented sand. Environmental Earth Sciences. 2019, 78(24):688
[25] Liu XL*, Liang T, Wang SJ, Nawnit K. A fractal model for characterizing hydraulic properties of fractured rock mass under mining influence. Geofluid. 2019. 2019: 8391803
[26] Liu XL*, Wang F, Huang J, Wang SJ, Zhang ZZ, Nawnit K. Grout diffusion in silty fine sand stratum with high groundwater level for tunnel construction. Tunnelling and Underground Space Technology. 2019, 93: 103051.
[27] Han GF, Chen Y, Liu M, Liu XL*. Differences in Performance of Models for Heterogeneous Cores during Pulse Decay Tests. Appl. Sci. 2019, 9: 3206.
[28] Guofeng Han, Yang Chen, Xiaoli Liu*. Investigation of analysis methods for pulse decay tests considering gas adsorption. Energies. 2019, 12(13):2562.
[29] Qiuhao Du, Xiaoli Liu*, Enzhi Wang, Jianping Zuo, Weimin Wang, Sijing Wang. Effects of CO2-Water-Coal Interaction on Minerals Content and Pore Characteristics. Journal of Rock Mechanics and Geotechnical Engineering. 2020, 12(2): 326-337
[30] Chi Liu, Xiaoli Liu*, Xiaochu Peng, Enzhi Wang, Sijing Wang. Application of 3D-DDA integrated with unmanned aerial vehicle (UAV) photogrammetry for stability analysis of a blocky rock mass slope. Landslides. 2019, 16: 1645–1661.
[31] Hebing Luan, Xiaoli Liu*, Enzhi Wang, Tao Liang, Zhiguo Cao. The effect of discontinuity density on key strata threshold span in longwall panels. Journal of Geophysics and Engineering. 2019, 16(2): 289-296
[32] Shuhong Dai*, Xiaoli Liu*, Kumar Nawnit. Experimental study on the fracture process zone characteristics in concrete utilizing DIC and AE method. Appl. Sci. 2019, 9(7), 1346.
[33] Huan Sun, Xiaoli Liu*, Jianbo Zhu. Correlation fractal characterization of stress and acoustic emission during coal and rock failure under multilevel dynamic loadings. International Journal of Rock Mechanics and Mining Sciences. 2019, 117: 1-10
[34] Zuo Jianping, Chen Yan, Liu Xiaoli. Crack evolution behavior of rocks under confining pressures and its propagation model before peak stress. Journal of Central South University. 2019, 26: 3045−3056
[35] Zhang, Zhenya, Liu, Xiaoli*, Wen, Xiaodong*. Enhance absorption based on the resonance of localized surface plasmon modes in a metamaterial absorber. Journal of Infrared and Millimeter Waves. 2018, 37(5): 533-539
[36] Ke Man, Xiaoli Liu*, Ju Wang, Xiyong Wang. Blasting Energy Analysis of the Different Cutting Methods. Shock and Vibration. 2018, 9419018
[37] Tang Zhili, Liu Xiaoli*, et al. Stability evaluation of deep-buried TBM construction tunnel based on microseismic monitoring technology. Tunnelling and Underground Space Technology. 2018,81: 512–524
[38] Chen Xu, Xiaoli Liu*, Sijing Wang, Enzhi Wang. Rockburst prediction and classification based on the ideal-point method of information theory. Tunnelling and Underground Space Technology. 2018,81: 382–390
[39] Tao Liang, Xiaoli Liu*, Sijing Wang, Enzhi Wang, Quansheng Li. Study on the fractal characteristics of fracture network evolution induced by mining. Advances in Civil Engineering. 2018, 9589364
[40] Xiaoli Liu*, Guofeng Han, Enzhi Wang, Sijing Wang, Kumar Nawnit. Multiscale hierarchical analysis of rock mass and prediction of its mechanical and hydraulic properties prediction. Journal of rock mechanics and geotechnical engineering. 2018, 10(4): 694-702
[41] Guan YP, Liu XL*, Wang EZ, Wang SY, Wang SJ, Zhong JW. Quantitative Characterization Method for the Microcontacts and Macrocontacts of Two-Dimensional Granular Materials. International Journal of Geomechanics-ASCE. 2018,18(4): 04018016.
[42] Yu Y, Liu X*, Wang E, Fang K. Dam Safety Evaluation Based on Multiple Linear Regression and Numerical Simulation. Rock mechanics and rock engineering. 2018, 51:2451-2467
[43] Ke Man, Ju Wang, Xiaoli Liu. Dynamic Tensile Properties of Granite Varied with Depths under a Similar Loading Rate. Advances in Civil Engineering. 2018, 6048312
[44] Ke Man, Xiaoli Liu. Dynamic Fracture Toughness and Dynamic Tensile Strength of the Rock from Different Depths of Beijing Datai Well. Advances in Civil Engineering. 2018, 2567438
[45] Ke Man, Xiaoli Liu, Ju Wang, Xiyong Wang. Directional Blasting Technology of Slit Charge for Geological Disposal of High-Level Radioactive Waste. Advances in Civil Engineering. 2018, 6401545
[46] Wang Saisai, Zhang Zhenya, Liu Xiaoli. Synthesis, Anti-corrosion Performance and Mechanism Research of Amphoteric Gemini Surfactant(TCDSQ-22) as Corrosion Inhibitor on Stainless Steel. Journal of the Chemical Society of Pakistan. 2018, 40(3): 590-594
[47] Guan Y, Liu X*, Wang E, Wang S. The Stability Analysis Method of the Cohesive Granular Slope on the Basis of Graph Theory. Materials. 2017, 10(3):240.
[48] Du Q, Liu X*, Wang E, Wang S. Strength Reduction of Coal Pillar after CO2 Sequestration in Abandoned Coal Mines. Minerals. 2017, 7(2):26.
[49] Wei X, Liu X*, Duan Y, Feng J. Property transformation of a modified sulfoaluminate grouting material under pressure circulation for a water-sealed underground oil cavern. Construction and Building Materials. 2017, 140:210-220
[50] Li S, Liu X, Li R, Su Y. Shear deformation dominates in the soft adhesive layers of the laminated structure of flexible electronics, International Journal of Solids and Structures. 2017,110:305-314, http://dx.doi.org/10.1016/j.ijsolstr.2016.12.006
[51] Xu C, Hu C, Liu X*, Wang S. Information Entropy in Predicting Location of Observation Points for Long Tunnel. Entropy. 2017, 19:332.
[52] Guan Y, Wang E, Liu X*, Wang S, Luan H. The Quantified Characterization Method of the Micro-Macro Contacts of Three-Dimensional Granular Materials on the Basis of Graph Theory. Materials. 2017, 10(8):898.
[53] Zhijia Zheng, Enzhi Wang, Xiaoli Liu, Zhuoping Duan*, Liansheng Zhang, Zhuocheng Ou, Jianwen Zhong. The Dynamic Response of Brittle Materials under Impact Loading. International Journal of Nonlinear Sciences and Numerical Simulation. 2017, 18(2): 115–127
[54] Guanhong He, Enzhi Wang*, Xiaoli Liu. Modified governing equation and numerical simulation of seepage flow in a single fracture with three-dimensional roughness. Arabian Journal of Geosciences. 2016, 9(1): 81.
[55] Shuhong Dai, Liming Dai*, Yishan Pan, Xiaoli Liu. Concrete Stress Intensity Factor Evaluation With a Digital Image Correlation Approach. Journal of Testing and Evaluation. 2016, 44(1): 615-624.
[56] Peng Lin*, Xiaoli Liu, Senying Hu, Pujian Li. Large Deformation Analysis of a High Steep Slope Relating to the Laxiwa Reservoir, China , Rock Mechanics and Rock Engineering. 2016, 49(6): 2253-2276.
[57] Ke Man*, Hongsu Ma, Xiaoli Liu, Fengqiang Gong, Zhenming Chen. Research on the static and dynamic properties of the granite in Xinjiang Province Tianhu Area for the geological disposal of the high level radioactive waste, 2nd International Conference on Rock Dynamics and Applications (RocDyn), China, Suzhou, 2016.
[58] Xiaoli Liu*, Sijing Wang, Shanyong Wang, Enzhi Wang. Fluid-driven fractures in granular materials. Bulletin of Engineering Geology and the Environment. 2015,74(2):621-636.
[59] Xiaoli Liu*, Peng Lin, Enzhi Wang, Sijing Wang. Coupled Hydro-Mechanical Analysis for Rainfall-Induced Failure of Fractured Rock Slopes. Engineering Geology for Society and Territory – Volume 2. 2015, 839-843.
[60] Xuefei Wei, Yunling Duan, Jinming Feng, Xiaoli Liu. Derive grouting technology in rock microfissure. Transit Development in Rock Mechanics – Cai, Yang & Wang (Eds). 2015, 723-728.
[61] Peng Lin, Xiaoli Liu, Weiyuan Zhou, Renkun Wang, Shanyong Wang. Cracking, stability and slope reinforcement analysis relating to the Jinping dam based on a geomechanical model test. Arabian Journal of Geosicences. 2015, 8:4393-4410
[62] Peng Lin, Xiaoli Liu, Hong-Xin Chen, Jinxie Kim. Ant Colony Optimization Analysis on Overall Stability of High Arch Dam Basis of Field Monitoring. The Scientific World Journal. 2014, 2014:483243
[63] Yang Yu, Enzhi Wang, Jianwen Zhong, Xiaoli Liu, Penghui Li, Mei Shi, Zhiguo Zhang. Stability analysis of abutment slopes based on long-termmonitoring and numerical simulation. Engineering Geology. 2014,183: 159-169.
[64] Qifeng Lv*, Enzhi Wang, Xiaoli Liu, Sijing Wang. Determining the intrinsic permeability of tight porous media based on bivelocity hydrodynetics, Microfluidics and Nanofluidics. 2014, 16(5): 841-848.
[65] Sun Liang, Zou Caineng, Liu Xiaoli, Zhu Rukai and Wang Xiaoqi. A static resistance model and the discontinuous pattern of hydrocarbon accumulation in tight oil reservoirs. Petroleum Science. 2014, 11 :469-480.
[66] Jianxin Wang, Xiaoli Liu. A preliminary study of joint effect of earthquake disturbing and rainfall on yiliang landslide. 2014 GeoShanghai International Congress: Advances in Soil Dynamics and Foundation Engineering, China,Shanghai, 2014-5-26, 2014-5-28.
[67] Guanhong He, Enzhi Wang, Xiaoli Liu. Numerical simulation study on flow in single fractures with different joint roughness coefficient. 2014 GeoShanghai International Congress: Rock Mechanics and Its Applications in Civil, Mining, and Petroleum Engineering, China, Shanghai, 2014-5-26, 2014-5-28.
[68] Xiaoli Liu*, Peng Lin, Enzhi Wang, Sijing Wang. Coupled Hydro-Mechanical Analysis for Rainfall-Induced Failure of Fractured Rock Slopes, 12th International IAEG Congress, ITALY, 2014-9-19.
[69] Qifeng Lv*, Xiaoli Liu, Enzhi Wang, and Sijing Wang. Analytical solution to predicting gaseous mass flow rates of microchannels in a wide range of Knudsen numbers. Physical Review E. 2013, 88(1): 013007
[70] Guofeng Han*, Xiaoli Liu, Enzhi Wang. Experimental study on formation mechanism of compaction bands in weathered rocks with high porosity. Science in China - Series E: Technological Sciences. 2013, 56 (10): 2563-2571.
[71] XiaoLi Liu*, Hongyan Li, Zhonggang Liu. THM Coupling Analysis and High Slope Deformation in A Reservoir. Disaster Advances. 2013, 6(s2): 46-54.
[72] XiaoLi Liu*, Liming Hu, Enzhi Wang, Qiang Xue. Study on Landfill Leachate Plumes with coupled Liquid-Solid Model. Disaster Advances. 2013, 6(7): 51-57.
[73] Xue Qiang*, Feng Xia-ting, Liu Lei, Chen Yi-jun,; Liu Xiao-li. Evaluation of pavement straw composite fiber on SMA pavement performances. Construction and Building Materials. 2013, 41: 834-843.
[74] Peng Lin, Xiaoli Liu. Study on cracking risk of Jinping high and steep slope, 4th International Symposium on Geotechnical Safety and Risk, ISGSR 2013, China, Hong Kong, 2013-12-4, 2013-12-6.
[75] Ke Man, Xiaoli Liu, Ju Wang, Rui Su,Yongqiang Zhu. Double Fracture Systems of Rock Flow for Geological Disposal of the High-Level Radioactive Waste. Applied Mechanics and Materials. 2013, 361-363: 912-916.
[76] Guanhong He*, Enzhi Wang, Xiaoli Liu. Analysis on Seepage Field and Seepage Control Measure around Kunlong Hydropower Project. 2nd International Conference on Civil Engineering, Architecture and Sustainable Infrastructure (ICCEASI 2013), Zhengzhou, 2013-7-13, 2013-7-15.
[77] Ke Man, Ju Wang, Rui Su, Xiaoli Liu, Yang Zhao, Biao Zhao. Theoretic seepage model of "water-rock-structural plane" considering the hydro-mechanical coupling mechanism, 2nd International Symposium of Mine Safety Science and Engineering, China, Beijing, 2013-9-21, 2013-9-23.
[78] XiaoLi Liu*, Peng Lin, Enzhi Wang, Guanhong He, Guofeng Han. CO2 geological sequestration modelling and injection induced fracturing analysis of the caprock, 3rd ISRM Symposium on Rock Characterisation, Modelling and Engineering Design Methods, SINOROCK 2013, China, 2013-6-18, 2013-6-20.
[79] Peng Lin, Xiaoli Liu, Shengzu Kang, C. Wang. Theoretical analysis on electromagnetic emission of rock fracturing process, 3rd ISRM Symposium on Rock Characterisation, Modelling and Engineering Design Methods, SINOROCK 2013, China, 2013-6-18, 2013-6-20.
[80] Xiaoli Liu*, Enzhi Wang, Guofeng Han, Shanyong Wang. Discontinuous Deformation Analysis for the Slope Stability in Jinping First Stage Hydropower Station, Southwestern China. Disaster Advances. 2012, 5(4): 1481-1485.
[81] Xiaoli Liu*, Shanyong Wang. Mine Water Inrush Forecasting During the Mining under Waters. Disaster Advances. 2012, 5(4): 876-881.
[82] Xiaoli Liu*, Sijing Wang, Enzhi Wang. A study on the uplift mechanism of Tongjiezi dam using a coupled hydro-mechanical model. Engineering Geology. 2011, 117(1-2):134-150.
[83] Fan, Yunyun*, Liu, Xiaoli, Wang, Enzhi, Wang, Sijing. Research on dynamic process of large-scale high-speed landslide disasters , 1st International Conference on Civil Engineering, Architecture and Building Materials, CEABM 2011, China,Hainan,Haikou, 2011-6-18, 2011-6-20.
[84] Xiaoli Liu*, Enzhi Wang, Sijing Wang. Bonded-particle modelling of fluid-driven fractures in granular materials, GeoProc2011, Australia, 2011-7-6, 2011-7-9.
[85] Yunyun Fan, Sijing Wang, Enzhi Wang, Xiaoli Liu. Influence of obstacle angle on granular flow, International Symposium on Geomechanics and Geotechnics - From Micro to Macro, China, 2010-10-10, 2010-10-12.
[86] Xiaoli Liu*, Sijing Wang, Enzhi Wang. Digital Fractured Rock Mass Model and Its Application on Determination of REV for Engineering Properties Evaluation, Sinorock 2009, Hong Kong, 2009-5-19, 2009-5-22.
[87] Liu XL, Wang SJ, Wang EZ. Mathematical model of coupled Thermo-Hydro-Mechanical (THM) processes and its application in geo-hazards, 12th International Symposium on Water-Rock Interaction (WRI-12), Kunming, 2007-7-31, 2007-8-5.
[88] Xiaoli Liu*, Sijing Wang, Enzhi Wang. Study on the uplift mechanism of the dam body and rock masses on right side of Tongjiezi dam after water impounding using a coupled hydro-mechanical model, Sichuan province, China, GeoProc 2006, China, 2006-5-22, 2006-5-24.
[89] Xiaoli Liu*, Sijing Wang, Enzhi Wang, et al. Double-medium constitutive model of geological material in uniaxial tension and compression. Applied Mathematics and Mechanics (English Edition). 2006, 27(10): 1361-1372.
[90] Sijing Wang*, Xiaoli Liu, Enzhi Wang. Hydro-geodynamic analysis and its application, The 2nd International Conference on Coupled THMC Processes in Geosystems (Geoproc2006), China, Nanjing, 2006-5-21, 2006-5-24.
[91] Xue Q*, Liang B, Liu XL, Li HY. Fluid-solid coupling mathematical model of contaminant transport in unsaturated zone and its asymptotical solution, Applied Mathematics and Mechanics (English Edition ). 2003, 24(12):1475-1485.
[92] Xiaoli Liu*, Bing Liang, Qiang Xue. Research on mathematical model of pollutant transport in unsaturated-saturated fractured rocks,The International Conference of GIS and Remote Sensing in Hydrology, Water Resources and Environment(ICGRHWE), 2003-9-15, 2003-9-18.
[93] Xiaoli Liu*, Bing Liang, Qiang Xue. Model and numerical simulation for contaminant transporting in fractured rock systems. Geotechnical Engineering in Urban Construction (Proceedings of the Sino-Japanese Symposium on Geotechnical Engineering), China, 2003-10-29, 2003-10-30.
[94] 满轲, 刘晓丽, 宋志飞, 宋小软, 程海丽, 郭占峰, 柳宗旭, 于云鹤. 静−动态加载条件下岩石断裂特性及断口形貌特征研究. 中南大学学报(自然科学版). 2021, 52(8): 2876−2886.
[95] 苏宝, 刘晓丽, 卫晓波, 高歌, 王云鹏. 井间超高密度电阻率法溶洞探测研究.物探与化探. 2021, 45(5): 1354-1358.
[96] 满轲, 刘晓丽. 不同爆破掏槽形式的反应频谱综合分析. 工程力学. 2021,38(07): 52-63
[97] 孙欢, 刘晓丽, 王恩志, 张建民, 王思敬, 刘驰. 岩石破裂过程中裂隙流体X射线造影试验及应用. 清华大学学报(自然科学版). 2021,61(08): 778-791.
[98] 宋丹青, 黄进, 刘晓丽, 王恩志. 地震作用下岩体结构及岩性对高陡岩质边坡动力响应特征的影响. 清华大学学报(自然科学版). 2021,61(08): 873-880.
[99] 满轲, 刘晓丽, 宋志飞, 郭占峰, 柳宗旭, 于云鹤. 岩石静态与动态断裂韧性的宏细观试验. 清华大学学报(自然科学版). 2021,61(08): 799-808.
[100]宋丹青; 黄进; 刘晓丽. 地震作用下层状岩质边坡动力响应. 湖南大学学报(自然科学版). 2021,48(05):113-120.
[101]王维民, 王恩志, 刘晓丽, 张鲁军. 淤积土硬化材料力学性能研究. 河北水利电力学院学报. 2021, 31(01): 1-9
[102]宋丹青; 黄进; 刘晓丽; 张鲁军; 王恩志. 地震作用下金沙江某跨江桥梁岩质岸坡动力响应分析. 工程技术科学, https://doi.org/10.15961/j.jsuese.202000422
[103]徐琛; 刘晓丽; 王恩志; 王思敬. 基于耦合FDM-DEM方法的TBM滚刀最优化研究. 土木工程学报. 2020,53(S1):286-299
[104]刘晓丽, 王恩志. 缅甸滚弄水电站坝基渗流过程及渗控优化精细模拟. 河北水利电力学院学报. 2020,30(04): 1-9
[105]满轲, 刘晓丽. 周边空孔效应对爆破振速及围岩损伤的影响研究. 工程力学. 2020,37(11):127-134
[106]徐琛, 刘晓丽, 张鲁军, 毛宗原, 周建军, 王思敬. 耦合地质模型的TBM隧道施工过程进度仿真预测. 隧道与地下工程灾害防治. 2020,2(02): 41-46.
[107]孙欢, 刘晓丽, 王恩志, 刘驰, 张建民. 碳酸盐岩破裂过程中管道—裂隙水非线性流动特性试验研究. 中国岩溶. 2020,39(04): 500-508.
[108]张东, 刘晓丽, 王恩志. 非均匀多孔介质等效渗透率的普适表达式. 水文地质工程地质. 2020, 47(4): 35-41.
[109]孙欢, 刘晓丽, 王恩志, 张东. 基于X射线断层扫描预测岩石单轴抗压强度. 岩石力学与工程学报. 2019, 38(Supp.2):3575-3582
[110]梁涛,刘晓丽,王思敬. 采动裂隙扩展规律及渗透特性分形研究. 煤炭学报. 2019, 44(12): 3729-3739
[111]刘晓丽,曹志国,陈苏社,高岩堂. 煤矿分布式地下水库渗流场分析及优化调度. 煤炭学报. 2019, 44(12):3693-3699
[112]满轲,刘晓丽,王驹,岳中文,王锡勇,许鹏. 高放废物地质处置切缝药包定向爆破技术研究. 工程力学. 2019, 36(Supp1.):316-323, 328
[113]关岩鹏, 张玉芳, 刘晓丽. 颗粒离散元数值模拟中的宏细观接触力计算方法. 铁道建筑. 2019, 59(5): 85-88.
[114]关岩鹏, 张玉芳, 刘晓丽. 库水位波动条件下某边坡变形特征与稳定性的颗粒流分析. 勘察科学技术. 2019(1): 20-26
[115]杜秋浩, 刘晓丽, 王维民, 王恩志, 钟建文, 王思敬. 超临界CO2-水-煤相互作用后冲击载荷下煤的动态响应.煤炭学报. 2019, 44(11):3453-3462.
[116]孙欢, 刘晓丽, 陈宇龙. 多级动荷加载条件下煤岩应力–声发射耦合特性试验. 岩石力学与工程学报. 2018, 37(增2): 4076-4085.
[117]徐琛, 胡程科, 刘晓丽, 王思敬, 朱瑜劼. 基于Markov过程与信息熵法的长隧道勘探位置优化. 地下空间与工程学报. 2018, 14(6): 1611-1617.
[118]朱瑜劼, 刘晓丽, 王恩志, 王思敬, 钟建文. 基于蒙特卡洛法的三峡库区泄滩边坡稳定性风险评估. 水利水电技术. 2018, 49(12): 154-161.
[119]魏雪斐, 刘晓丽, 段云岭, 冯金铭, 乔楠, 郭利民. 压力循环作用下灌浆材料性能演化及其在地下水封石油储库工程中的应用. 现代隧道技术. 2018, 55(3): 220-228.
[120]张勇, 刘晓丽*, 王恩志. 稀疏裂隙岩体核废料处置库近场岩石热应力的半解析计算分析. 地下空间与工程学报. 2018, 14(3):741-747
[121]汤志立, 刘晓丽, 李超毅, 秦鹏翔, 徐千军. 深埋TBM 隧道施工微震监测规律. 清华大学学报(自然科学版),2018, 58(5): 461-468.
[122]魏雪斐, 刘晓丽*, 段云岭, 冯金铭. 大型地下水封储库围岩快速补强灌浆体系. 地下空间与工程学报. 2018, 14(2):200-211.
[123]满轲, 刘晓丽*, 宫凤强, 马洪素, 王驹. 不同赋存深度新疆天湖花岗岩的动态拉伸力学特性研究. 工程力学. 2018, 35 (3): 200-209
[124]王芳, 刘晓丽*, 王恩志, 刘中港, 魏天清. 含水砂层的剪切流变力学特性试验分析. 地下空间与工程学报. 2018, 14(2):200-211
[125]满轲, 刘晓丽, 宫凤强, 马洪素, 陈振鸣, 王驹. 高放废物地质处置新疆预选区天湖地段花岗岩的静态及动态力学特性研究. 爆炸与冲击. 2017, 36(17):146-156.
[126]徐琛, 刘晓丽*, 王恩志, 王思敬. 基于组合权重-理想点法的应变型岩爆五因素预测分级. 岩土工程学报. 2017, 39(12):2245-2252.
[127]刘晓丽, 王恩志,王思敬. 水岩耦合过程及多尺度效应研究进展. 中国学科发展战略研究 (水利科学与工程前沿). 2017: 823-838
[128]吕小宁,刘晓丽*,段云岭,汤志立. 地下能源储库群激光测量模拟与参数设计. 清华大学学报(自然科学版),2017,57(7):713-719.
[129]满轲, 刘晓丽, 王锡勇, 陈振鸣, 陈亮, 王驹. 掏槽方式对光面爆破效果的影响研究.科学技术与工程. 2017,17(19):92-98.
[130]吕小宁, 刘晓丽*, 段云岭, 梁建毅. 地下能源储库群容积激光测量方法及现场实验. 中国激光. 2016, 43(10): 147-156.
[131]王振伟, 刘晓丽, 吕祥锋, 王俊, 李伟.含裂隙排土场边坡渗流与非连续变形耦合稳定控制研究. 露天采矿技术. 2016, 31(9):10-13.
[132]王建新, 张策, 郭啓良, 李兵, 刘晓丽. 水压致裂原地应力测试井下水压力数据采集系统及其应用研究. 岩石力学与工程学报. 2016, 35(S2):3971-3976.
[133]满轲, 刘晓丽, 王锡勇, 陈振鸣, 王驹. 周边孔炮眼间距对光面爆破效果的影响. 科学技术与工程. 2016,16(29):47-52.
[134]满轲, 刘晓丽*. 新疆天湖花岗岩的一维动静组合拉伸特性研究. 地下空间与工程学报. 2015, 11(S2):732-779.
[135]于洋, 刘晓丽*. 陡倾岩层矿区地应力回归与分析.地下空间与工程学报. 2015, 11(S2):750-755.
[136]满轲, 刘晓丽*等. 岩石动态断裂韧性测试的失稳判据研究.第14届全国岩石动力学学术会议暨工程安全与防护专题研讨会论文集. 2015, 236-242.
[137]刘中港, 刘晓丽*, 王恩志. 含水量对泥石流物源流变特性影响试验研究. 岩石力学与工程学报. 2015,34(V2):3830-3836.
[138]满轲, 刘晓丽*. 大尺度单裂隙介质应力–渗流耦合试验台架及其渗透系数测试研究.岩石力学与工程学报. 2015, 34(10):2064-2072.
[139]王建新, 刘晓丽, 王恩志. 垂直降雨入渗水势模型的推导及其试验验证. 水文地质工程地质. 2013, (02): 24-29.
[140]刘晓丽*, 林鹏, 韩国锋, 何冠鸿. 裂隙岩质边坡渗流与非连续变形耦合过程分析. 岩石力学与工程学报. 2013, 32(06): 1248-1256.
[141]林鹏, 刘晓丽, 胡昱, 许文彬, 李庆斌. 应力与渗流耦合作用下溪洛渡拱坝变形稳定分析. 岩石力学与工程学报. 2013, 32(06): 1145-1156.
[142]买合木提·巴拉提*, 王恩志, 刘晓丽, 虎胆·吐马尔白. 二塘沟水库右岸滑坡体稳定性分析. 水文地质工程地质. 2013, 40(02): 83-87.
[143]王建新; 高成玉; 郭啟良; 刘晓丽; 杨野; 尼泊尔上塔马克西水电站三维地应力测试分析, 岩石力学与工程学报. 2012, (S1): 3339-3344.
[144]胡波, 王思敬, 刘晓丽. 共面断续节理岩体直剪强度特性模型, 江苏大学学报(自然科学版). 2012, 33(05): 601-605.
[145]王恩志*, 韩国锋, 刘晓丽. 高孔隙岩石破损后渗透特性分析, 中国力学学会流体力学专业委员会, 中国广西桂林, 2012-11-12, 2012-11-15.
[146]韩国锋, 王恩志, 刘晓丽. 岩石损伤过程中的渗流特性. 土木建筑与环境工程. 2011,33(05):41-50.
[147]韩国锋, 王恩志, 刘晓丽. 压缩带形成过程中渗透性变化试验研究.岩石力学与工程学报. 2011, 30(05): 991-997.
[148]韩国锋, 王恩志, 刘晓丽. 侧向应力对裂隙渗透性的影响. 水文地质工程地质. 2011,38(04):38-42.
[149]韩国锋*, 王恩志, 刘晓丽. 岩石峰后非达西流问题的探讨. 岩土工程学报. 2011, 33(11): 1792-1796.
[150]胡波, 刘观标, 王思敬, 刘晓丽. 基于原型监测的特高拱坝软弱带置换效果评价. 水利学报. 2011, 42(07): 876-882.
[151]胡波*, 廖占勇, 刘晓丽. 小湾特高拱坝蓄水初期坝肩抗力体变形特性研究, 西北水电. 2011, S1: 30-34.
[152]宋志飞, 雷家好, 孙世国, 陈静, 刘晓丽. 复杂条件下煤层开采上覆岩体移动规律研究. 煤矿开采. 2011, 16(04): 95-96+112.
[153]刘晓丽*, 王恩志, 王思敬, 韩国锋. 含孔洞饱和岩体中水力作用的尺度敏感性. 岩石力学与工程的创新和实践:第十一次全国岩石力学与工程学术大会, 中国湖北武汉, 2010-10-16, 2010-10-19.
[154]樊赟赟*, 王思敬, 王恩志, 刘晓丽. 泥石流沿程侵蚀动力过程模拟分析. 岩石力学与工程学报. 2010, 29(S2): 4146-4152.
[155]胡波*, 赵海滨, 王思敬, 刘海宁, 彭运动, 刘晓丽, 张晓平. 隧道锚围岩拉拔模型试验研究及数值模拟. 岩土力学. 2009, 30(06): 1575-1582.
[156]樊赟赟*, 王思敬, 王恩志, 刘晓丽. 岩土材料剪切破坏点安全系数的研究. 岩土力学. 2009, 30(S2): 200-203.
[157]刘晓丽*, 王思敬, 王恩志. 单轴压缩岩石中缺陷的演化规律及岩石强度. 岩石力学与工程学报. 2008, 27(6): 1195-1201.
[158]刘晓丽*, 王恩志, 王思敬. 裂隙岩体表征方法及其在岩体水力学特性研究. 岩石力学与工程学报,2008, 27(9): 1814-1821.
[159]刘晓丽*, 王恩志, 王思敬. 裂隙岩体精细结构描述及工程特性数值试验. 岩石力学与工程学报. 2008, 27(增2): 3935-3940
[160]汪海涛*, 刘晓丽, 王思敬. 新疆伊犁南岸干渠黄土渠段湿陷性分析. 工程地质学报. 2008, 16(02): 222-227.
[161]刘晓丽*, 王恩志. 某井田水体下开采过程中地下水渗流模拟及涌水量预测. 西安石油大学学报(自然科学版). 2007, 22(s1): 1-5.
[162]陈佩佩*, 许延春, 王恩志, 刘晓丽, 徐法奎. 玉舍河下煤层开采安全性分析. 煤田地质与勘探. 2007, 35(04): 46-49.
[163]刘晓丽*, 王思敬, 王恩志. 含时间效应的膨胀岩膨胀本构关系. 水利学报. 2006, 37(2): 195-199.
[164]刘晓丽*, 王思敬, 王恩志, 薛强. 铜街子水电站坝基岩石单轴压缩与侧限膨胀的试验研究. 水文地质工程地质. 2006, 2: 45-49.
[165]刘晓丽*, 王恩志, 王思敬, 刘顺桂. 裂隙岩体渗透性研究. 工程地质学报(增刊). 2006, 14(Suppl.): 344-349.
[166]刘晓丽*, 王思敬, 王恩志, 薛强. 单轴作用下岩土材料的双重介质本构模型. 应用数学和力学. 2006, 27(10): 1193-1201.
[167]陈运平*, 王思敬, 王恩志, 刘晓丽, 西绕甲措, 杨刚, 樊赟赟. 铜街子水电站诱发地震特征及其地圈动力学分析. 第九届全国岩石力学与工程学术大会, 中国辽宁沈阳, 2006-7-1至2006-7-3.
[168]刘晓丽*, 梁冰, 王思敬, 李宏艳. 水气二相渗流与双重介质变形的流固耦合数学模型. 水利学报. 2005, 36(04): 405-412.
[169]梁冰*, 刘晓丽, 李宏艳. 矿产资源枯竭型城市的生态环境问题-以辽宁省阜新市为例. 中国地质灾害与防治学报. 2005, 16(03): 122-125.
[170]刘晓丽*, 梁冰, 薛强. 难降解有机污染物在土壤中释放的动力学模型研究. 岩土力学. 2004, 25(2):207-210.
[171]刘晓丽*,梁冰,李宏艳,多孔介质中水气二相流动力学行为分析. 中国科学技术大学学报(增刊),2004, 34(Z1): 462-469.
[172]梁冰*, 刘晓丽, 薛强. 低渗透地下环境中水-岩作用的渗流模型研究. 岩石力学与工程学报. 2004, 23(05): 745-750.
[173]薛强*, 梁冰, 刘建军, 刘晓丽. 矸石山渗滤液在地下水系统中运移的仿真分析. 系统仿真学报. 2004, 16(02): 356-359.
[174]刘晓丽*, 梁冰, 薛强. 多孔介质渗透率分形描述. 水科学进展. 2003, 14(6):769-773.
[175]梁冰*; 刘晓丽; 薛强; 地下工程与环境及其关键力学问题. 中国土木工程学会第九届土力学及岩土工程学术会议, 中国北京, 2003-9-15至2003-9-18.
[176]刘晓丽*, 梁冰, 薛强. 地下水环境中有机污染物迁移转化动力学模型的研究. 工程勘察. 2003, (01): 24-28+23.
[177]薛强*, 梁冰, 刘建军, 刘晓丽. 环境介质中有机污染物运移的数值模型. 应用与环境生物学报. 2003, 9(06): 647-650.
[178]梁冰*, 薛强, 刘晓丽. 多孔介质非线性渗流问题的摄动解. 应用力学学报. 2003, 20(04): 28-32.
[179]薛强*, 梁冰, 刘晓丽, 陈贺. 土壤水环境中有机污染物运移环境预测模型的研究. 水利学报. 2003, (06): 48-55.
[180]薛强*, 梁冰, 孙可明, 刘晓丽. 填埋气体迁移气-热-力耦合动力学模型的研究. 应用力学学报. 2003, 20(02): 54-59+159.
[181]梁冰*, 薛强, 刘晓丽. 煤矸石中硫酸盐对地下水污染的环境预测. 煤炭学报. 2003, 28(05): 527-530.
[182]薛强*, 梁冰, 刘晓丽. 有机污染物运移的动力学预测模型及模型参数分析. 工程勘察. 2003, (06): 17-20.
[183]薛强*, 梁冰, 刘晓丽, 李宏艳. 污染物在非饱和带内运移的流固耦合数学模型及其渐近解. 应用数学和力学. 2003, 24(12): 1309-1318.
[184]薛强*, 梁冰, 刘晓丽. 燕允鹏. 辽宁省阜新地区地下水水质特征及污染防治措施. 中国地质灾害与防治学报. 2003, 14(03): 91-95.
[185]薛强*, 梁冰, 刘晓丽. 填埋场中气体运移的非稳定耦合渗流数学模型. 岩土力学. 2002, 23(02): 191-195.
[186]梁冰*, 薛强, 刘晓丽. 油气田地区土壤-水环境中有机污染的数值模拟及模型预测. 中国地质灾害与防治学报. 2002, 13(03): 21-24.
[187]梁冰*, 刘晓丽, 薛强. 非等温入渗条件下土壤中水分运移的解析分析. 辽宁工程技术大学学报(自然科学版). 2002, 21(06): 741-744.
[188]梁冰*, 薛强, 刘晓丽. MATLAB在垃圾填埋气体运移数值可视化中的应用. 安全与环境学报. 2002, 2(06): 37-39.
[189]薛强*, 梁冰, 刘晓丽. 有机污染物在土壤中迁移转化的研究进展. 土壤与环境. 2002, (01): 90-93.
[190]薛强*, 梁冰, 刘晓丽. 土壤气抽出过程中挥发性有机污染物运移动力学模型的研究. 灌溉排水. 2001, 20(04): 5-9.
特邀报告(近5年)
[1] Softening mechanism and experimental study of red-bed soft rock. ARMS11-The 11th Asian Rock Mechanics Symposium, Chinese Society for Rock Mechanics and Engineering, Beijing, October 23, 2021
[2] 岩体多尺度结构演化与工程影响关键带.第五届谷德振讲座,中国地质学会,郑州,2021年9月25日
[3] 人类工程活动影响下水岩作用及水环境演化.第四届全国环境岩土力学与工程青年学术论坛,中国岩石力学与工程学会,桂林,2021年9月26日
[4] 多介质环境中的渗流特性及工程应用.第十六届全国渗流力学大会,中国力学学会,葫芦岛,2021年7月30日
[5] THMC多元关联分析及岩土工程影响关键带.第十一届全国工程地质大会,中国地质学会,武汉,2020年10月17日
[6] 水资源地下分质储用技术与储库工程智能建造.第十七次中国岩石力学与工程学术年会,中国岩石力学与工程学会,2020年10月26日
[7] New idea on coal-water coordinate mining: Distributed underground reservoirs construction technology in mined out area.Seminar of Impacts of Geotechnical Engineering,the Argentine Society of Geotechnical Engineering, Buenos Aires, Sep.20,2019.
[8] 基于微震震源机制反演的岩爆风险评估方法.第三届全国隧道掘进机工程技术研讨会,中国岩石力学与工程学会,2019年12月1日
[9] 地下水库工程及其动力响应分析.首届交通岩土交叉学科高端论坛暨2018年山东大学齐鲁交通学院交叉学科沙龙,山东大学,2018年11月30日
[10] 隧道围岩损伤区分布与判识.2018中国隧道与地下工程大会(CTUC)暨中国土木工程学会隧道及地下工程分会第二十届年会, 中国土木工程学会,2018年11月5日
[11] CO2-水-煤作用下煤岩体渗透特性演化规律.首届全国青年渗流力学学术会议暨华中地区岩石物理学术前沿论坛、湖北省第三届渗流力学前沿论坛,中国地质大学,2018年9月21日
[12] 地下工程影响下水岩作用及水环境演化.第十次青年工程地质论坛,中国工程地质学会工程地质专委会,2018年9月8日
[13] 地下水库及地下水资源高效利用.京津冀-港澳台能源绿色开发及低碳城市建设论坛-2018海峡两岸暨港澳青年科学家学术活动,中国岩石力学与工程学会,2018年8月15日
[14] 孔隙-裂隙介质的渗流多尺度特性.第十五届全国试验力学大会,中国力学学会、国家自然科学基金委员会,2018年8月7日
[15] 深部长隧道TBM掘进微震监测与岩爆预测.中国科协第335次青年科学家论坛,中国科学技术协会、中国岩石力学学会,2017年11月18日
发明专利
[1] 一种智能人工降雨模拟装置(ZL201310449394.4),授权,排名第1
[2] 一种具有柔性坡面的边坡变形模型试验装置(ZL201310449431.1),授权,排名第1
[3] 降雨与库水联合作用下大型滑坡智能模型试验系统(ZL201310449395.9),授权,排名第1
[4] 一种试验模型及其制作方法(ZL201510604551.3),授权,排名第1
[5] 一种用于模拟岩层中的裂缝的模拟模型及其制作方法(ZL201510604699.7),授权,排名第1
[6] 煤矿地下水库煤柱坝体地震安全性的检测方法(CN201510604511.9),公开,排名第3
[7] 一种用于观测岩层表面位移的试验模型及其制作方法(ZL201510604903.5),授权,排名第1
[8] 模拟泥石流起动的大变形十字板头剪切流变试验系统(CN201610081275.1),公开,排名第1
[9] 摆锤式水岩耦合试验动力加载设备与方法(ZL201610081291.0),授权,排名第2
[10] 模拟沟床堆积物在上游泥石流扰动下的起动试验系统(ZL201610081047.4),授权,排名第1
[11] 一种隧道地质勘探方法、系统及微型掘进机(ZL201610081019.2),授权,排名第1
[12] 一种煤矿高矿化度矿井水地下分质储用方法(CN201710137148.3),公开,排名第3
[13] 一种用于模拟煤矿地下封闭空间的试验装置(ZL201810089233.1),授权,排名第1
[14] 一种节理岩体试样超声波测试设备(ZL201810155601.8),授权,排名第2
[15] 一种SHPB用充液节理岩体试样液体施加装置及方法(ZL201810283479.2),授权,排名第2
[16] 一种法兰式SHPB用充液节理岩体试样液体施加装置及方法(ZL201810572072.1),授权,排名第2
[17] 一种露天煤矿地下水库、水库储水体及水库库容计算方法(CNL201810985153.4),公开,排名第1
[18] 一种普适煤矿地下水库及其建造方法(CN201810982995.4),公开,排名第1
[19] 一种用于模拟煤层开采的模拟系统及模拟试验方法(ZL201510604576.3),授权,排名第1
[20] 一种用于隧道掘进的掘进机器人及远程移动终端指挥系统(CN201910068376.9),公开,排名第5
[21] 一种包含心墙堆石挡水坝结构的露天煤矿地下水库(CN201810983622.9),公开,排名第3
[22] 一种防治地下水库表土盐渍化的方法及配套设施(CN201911220140.9),公开,排名第2
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[24] 一种煤矿地下水库底板渗透性探测及稳定性评价方法(CN202010460390.6),公开,排名第5
[25] 一种地下工程用组合式分级可控封孔器装置及方法(CN202011047902.2),公开,排名第2
[26] 一种钻孔间距可调整的掘进装置及掘进机(CN202011056908.6),公开,排名第2
[27] 一种隧道掘进机的钻孔设备及隧道掘进机(CN202011057419.2),公开,排名第2
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[30] 一种地下工程用智能钻孔装置及掘进机(CN202011057262.3),公开,排名第2
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软件著作权
[1] 数字地质工程建模及三维可视化系统 DigGeo3D, 2009
[2] 三相渗流动力学模拟系统 DynamicFlow 1.0, 2010
[3] 多场多尺度复杂油气渗流模拟系统 Petro4M 1.0, 2010
[4] 地下防渗帷幕工程综合信息平台ASCCIP 1.0 (Anti-Seepage Curtain Comprehensive Information Platform), 2013
水利工程系
