人才
蘭恒星
文章來源: | 發布時間:2016-09-09 | 【打印】 【關閉】
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????蘭恒星,男,中國科學院地理科學與資源研究所,地理信息科學與技術全國重點實驗室研究員、博士生導師。
????目前任國際工程地質與環境協會(IAEG)滑坡命名方法專委會主席、國際期刊《Engineering Geology》、《Bulletin of Engineering Geology and the Environment》、《Journal of Mountain Science》編委、《Geoenvironmental Disaster》副主編等職。曾獲第七屆黃汲清青年地質科學技術獎等獎項。
研究領域與研究方向:
主要從事多尺度巖土體變形破壞機理、環境與地質災害動力學過程模型與風險分析的理論和應用基礎研究。
教育背景:(倒序排列)
1998 -2001中國科學院地質與地球物理研究所,獲博士學位
1995 -1998山東科技大學地球科學系,獲碩士學位
1991 -1995山東科技大學地球科學系,獲學士學位
工作經歷:(倒序排列)
2009-04~現在,中國科學院地理科學與資源研究所,研究員
2004-05~2009-04,加拿大阿爾伯塔大學、加拿大地面災害風險分析中心,研究工程師、研究組長
2004-02~2004-04,香港大學,研究助理
2003-08~2004-02,中國科學院地理科學與資源研究所,副研究員
2001-09~2003-07,中國科學院地理資源所資源與環境信息系統國家重點實驗室,博士后
科研業績:
????主要從事巖土體變形破壞機理、地質災害動力學與風險分析的理論和應用基礎研究。主持了國家自然科學基金國家杰出青年基金、國家自然科學基金重大專項項目、國家自然科學基金國家重大科研儀器研制項目等多個科研項目、課題。已發表學術論文300余篇,其中SCI檢索論文150余篇,授權專利50余項。
????近年來主要學術成績包括:提出了多尺度巖土體變形破壞的微觀各向異性控制理論,代表性成果在Web of Science引用率國際排名領先;創建了集成GIS系統的三維分布式地質災害動力學過程模型,在全球40個國家的學術界和工程界得到成功應用,成為國際主流模型;面向國家減災和重大工程實際問題,完成了一系列獲得國家領導人批示的科學咨詢研究。
科研項目:
國家自然科學基金委員會,重大項目,黃河流域地質地表過程與重大災害效應,2021/01 ~ 2024/12,主持
國家自然科學基金委員會,國家重大科研儀器研制項目,復雜結構黃土邊坡工程地質自適應原位協同探測系統,2020/01 ~ 2025/12,主持
國家自然科學基金委員會,重大項目課題,項目:川藏鐵路重大災害風險識別與預測—課題3:川藏鐵路重大災害風險識別與預測,2020/01 ~ 2024/12,主持
國家自然科學基金委員會,重大項目課題,項目:黃土高原重大工程災變機理與防控—課題3:黃土邊坡滑移機理與治溝造地工程災變效應,2018/01 ~ 2022/12,主持
國家自然科學基金委員會,國家杰出青年科學基金項目,工程地質動力學與地質災害,2016/01 ~ 2020/12,主持
國家自然科學基金委員會,創新研究群體項目,項目:地理時空數據分析—子課題:地表過程大數據時空分析,2015/01 ~ 2020/12,參加
國家自然科學基金委員會,面上項目,分布式滑坡形變PSI(永久散射體干涉雷達)監測模型及技術,2015/01 ~ 2018/12,主持
國家自然科學基金委員會,面上項目,基于LIDAR和頻率分布的巖崩規模與關鍵過程研究,2013/01 ~ 2016/12,主持
國家自然科學基金委員會,面上項目,汶川地震災區高陡山體斜坡災害三維離散動力學機理及過程模擬預測,2011/01 ~ 2013/12,主持
國家自然科學基金委員會,青年科學基金項目,復雜環境下的泥石流動力學過程GIS模擬研究,2006/01 ~ 2008/12,主持
科學技術部,國家重點研發計劃項目課題,項目:石窟寺巖體穩定性預測及加固技術研究—課題一:卸荷帶石窟寺巖體耦合松動機制與失穩機理,2020/01 ~ 2022/12,主持
科學技術部,第二次青藏高原綜合科學考察研究子專題,任務九:地質環境與災害—專題四:重大工程擾動災害及風險—子專題二:藏東南-一江兩河區重大工程擾動災害及風險,2019/11 ~ 2022/10,主持
科學技術部,國家重點基礎研究發展計劃(973計劃)項目課題,項目:能源儲備地下庫群災變機制與防護理論研究—課題五:密集儲庫區底層變形機理與地面沉降監測,2009/01 ~ 2013/12,參加
科學技術部,國家科技支撐計劃項目課題,項目:中國重大自然災害風險等級綜合評估技術研究—課題五:承險過程分析與承險脆弱性綜合評估技術,2008/09 ~ 2011/12,參加
中國科學院,中國科學院戰略性先導科技專項(A類)子課題,專項:美麗中國生態文明建設科技工程—項目九:氣候變化條件下山地致災風險綠色調控關鍵技術與示范—課題三:山地致災風險定量評估關鍵技術與多尺度風險制圖—子課題一:山地風險綜合評價指標體系構建,2019/01 ~ 2023/12,主持
中國科學院,中國科學院戰略性先導科技專項(A類)子課題,專項:地球大數據科學工程—項目四:全景美麗中國—課題三:“三生”空間統籌優化與決策支持—子課題四:重大自然災害風險評估—專題一:地質災害風險評估,2018/01 ~ 2022/12,參加
中國科學院,中國科學院前沿科學重點研究項目,項目:南海典型吹填島礁沉降變形的時空過程與機理—課題二:南海典型吹填島礁沉降變形的監測與機理分析,2016/08 ~ 2021/07,參加
中科院STS項目課題,魯甸地震災后重建的地質災害綜合評估,2015年1月 ~ 2016年12月,主持
中國科學院,中科院戰略性先導科技專項(B類)課題,專項:頁巖氣勘探開發基礎理論與關鍵技術—項目三課題三子課題一:頁巖儲層壓裂的多尺度破裂力學機制,2014/01 ~ 2019/12,參加
中國科學院,百人計劃,地質災害過程模型研究,2009/01 ~ 2012/12,主持
中國工程院,中國工程院重大咨詢研究項目課題,項目:瓊東南盆地海底地質災害風險應對戰略研究—課題一:瓊東南盆地海底地質災害防控對策戰略研究成果集成,2021/11 ~ 2022/11,主持
中國工程院,中國工程院重大咨詢研究項目課題,項目:海西經濟區(閩江、九龍江等流域)生態環境安全與可持續發展研究—課題四:海西經濟區地質災害危險度劃分與防治對策研究,2010/03 ~ 2012/12,參加
代表性論著:(* 通訊作者)
1.Liang,Q.Y.,Lan,H.X.*,Zhou,Y.,Li,B.,Sun,W.F.,Liu,S.J.,Lv,W.J. (2024). Reverse Size Effect of the Unconfined Compressive Strength of Crystalline Rock: A Grain?Scale Perspective. Rock Mechanics and Rock Engineering.
2.Tian,N.M.,Lan,H.X.*,Li,L.P.,Peng,J.B.,Fu,B.J.*,Clague,J.J. (2025). Human activities are intensifying the spatial variation of landslides in the Yellow River Basin. Science Bulletin,70,263–272.
3.Lan,H.X.,Song,Z.T.*,Bao,H.*,Ma,Y.F.,Yan,C.G.,Liu,S.J.,Wang,J.T. (2024). Shear strength parameters identification of loess interface based on borehole micro static cone penetration system. Geoenvironmental Disasters,11,24.
4.Lan,H.X.*,Zhao,Z.,Li,L.P.,Li,J.H.,Fu,B.J.*,Tian,N.M.,Lai,R.X.,Zhou,S.,Zhu,Y.B.,Zhang,F.Y.,Peng,J.B.,Clague,J.J. (2024). Climate change drives flooding risk increases in the Yellow River Basin. Geography and Sustainability,5,193–199.
5.Li,L.P.,Lan,H.X.* (2024). Analytical ‘decisiveness’ as a robust measure of the absolute importance of landslide predisposing factors. International Journal of Digital Earth,17(1),2356161.
6.Lin,G.,Lan,H.X.*,Li,P.,Li,L.P.,Liu,S.J.,Sun,W.F. (2024). Role of rainfall temporal distribution on effective infiltration in the loess slope and prediction model. Engineering Geology,335,107541.
7.Liu,C.Q.,Bao,H.*,Lan,H.X.*,Li,L.,Chen,W.C.,Lv,H.T.,Liu,J.H.,Liu,S.J. (2024). Bedding effect on progressive crack propagation in layered sandstone grotto roof. Tunnelling and Underground Space Technology,152,105914.
8.Liu,C.Q.,Bao,H.*,Lan,H.X.*,Yan,C.G.,Li,C.B.,Liu,S.J. (2024). Failure evaluation and control factor analysis of slope block instability along traffic corridor in Southeastern Tibet. Journal of Mountain Science,21(6),1830–1848.
9.Liu,S.J.,Lan,H.X.*,Strom,A.,Li,L.P.,Bao,H. (2024). Spatial segmentation of Jiali Fault’s Holocene activity in the southeastern Tibetan Plateau. npj Natural Hazards,1,42.
10.Liu,X.*,Xu,X.Y.,Huang,L.,Wei,X.,Lan,H.X.* (2024). On characteristics of K0 value and shear behaviour of loess using triaxial test. Scientific Reports,14,12384.
11.Zhao,G.H.,Lan,H.X.*,Yin,H.Y.,Li,L.P.*,Strom,A.,Sun,W.F.,Tian,C.Y. (2024). Deformation,structure and potential hazard of a landslide based on InSAR in Banbar county,Xizang (Tibet). China Geology,7,203–221.
12.Zhao,Z.,Lan,H.X.*,Li,L.P.,Strom,A. (2024). Landslide spatial prediction using cluster analysis. Gondwana Research,130,291–307.
13.Zhu,Y.B.*,Zhang,Y.X.,Lan,H.X.*,Peng,J.B.,Zheng,H.T.,Zhao,D.,Yin,Y.M. (2024). Effect of crack depth on the initiation and propagation of crack-induced sliding in a paleosol area on a loess slope: Three-dimensional investigation based on model testing and laser scanning. Engineering Geology,342,107745.
14.Bao,H.,Tang,M.,Lan,H.X.*,Peng,J.B.,Zheng,H.*,Guo,G.M. (2023). Soil erosion and its causes in high-filling body: A case study of a valley area on the Loess Plateau,China. Journal of Mountain Science,20,182–196.
15.Cao,Y.M.,Lan,H.X.*,Li,L.P. (2023). Disaster Risk Assessment for Railways: Challenges and a Sustainable Promising Solution Based on BIM+GIS. Sustainability,15,16697.
16.Lan,H.X.*,Zhang,T.W.#,Peng,J.B.,Zhang,F.Y.,Li,L.P.,Wu,Y.M.,Tian,N.M.,Clague,J.J.* (2023). Large scale land reclamation and the effects on hydro-mechanical behavior in loess and loess-derived fill. Engineering Geology,323,107241.
17.Li,L.P.,Lan,H.X.* (2023). Bivariate Landslide Susceptibility Analysis: Clarification,Optimization,Open Software,and Preliminary Comparison. Remote Sensing,15(5),1418.
18.Liu,S.J.,Lan,H.X.*,Martin,C.D. (2023). Effect of disturbance on the progressive failure process of Eastern Himalayan Gneiss. Engineering Geology,312,106936.
19.Liu,X.,Wang,L.*,Liu,X.L.,Li,L.P,Zhu,X.C.,Chang,C.Y.,Lan,H.X.* (2023). Multispectral versus texture features from ZiYuan?3 for recognizing on deciduous tree species with cloud and SVM models. Scientific Reports,13,7369.
20.Tian,N.M.,Lan,H.X.* (2023). The indispensable role of resilience in rational landslide risk management for social sustainability. Geography and Sustainability,4,70–83.
21.Bao,H.,Liu,C.Q.,Lan,H.X.*,Yan,C.G.,Li,L.P.,Zheng,H.,Dong,Z.G. (2022). Time-dependency deterioration of polypropylene fiber reinforced soil and guar gum mixed soil in loess cut-slope protecting. Engineering Geology,311,106895.
22.Cao,Y.M.,Guo,W.,Wu,Y.M.,Li,L.P.*,Zhang,Y.X.,Lan,H.X.* (2022). An hourly shallow landslide warning model developed by combining automatic landslide spatial susceptibility and temporal rainfall threshold predictions. Journal of Mountain Science,19(12),3370–3387.
23.Lan,H.X.*,Liu,X.,Li,L.P.,Li,Q.W.,Tian,N.M.,Peng,J.B. (2022). Remote Sensing Precursors Analysis for Giant Landslides. Remote Sensing,14(17),4399.
24.Lan,H.X.,Peng,J.B.*,Zhu,Y.B.,Li,L.P.,Pan,B.T.,Huang Q.B.,Li,J.H.,Zhang,Q. (2022). Research on geological and surfacial processes and major disaster effects in the Yellow River Basin.SCIENCECHINA Earth Sciences,65(2),234–256.
25.Lan,H.X.*,Tian,N.M.,Li,L.P.*,Liu,H.J.,Peng,J.B.,Cui,P.,Zhou,C.H.,Macciotta,R.,Clague,J.J. (2022). Poverty control policy may affect the transition of geological disaster risk in China. Humanities and Social Sciences Communications,9,80.
26.Lan,H.X.*,Tian,N.M.,Li,L.P.*,Wu,Y.M.,Macciotta,R.,Clague,J.J. (2022). Kinematic-based landslide risk management for the Sichuan-Tibet Grid Interconnection Project (STGIP) in China. Engineering Geology,308,106823.
27.Lan,H.X.*,Zhang,Y.X.,Macciotta,R.,Li,L.P.*,Wu,Y.M.,Bao,H.,Peng,J.B. (2022). The role of discontinuities in the susceptibility,development,and runout of rock avalanches: a review. Landslides,19,1391–1404.
28.Li,L.P.*,Lan,H.X.*,Strom,A.,Macciotta,R. (2022). Landslide longitudinal shape: a new concept for complementing landslide aspect ratio. Landslides,19,1143–1163.
29.Li,L.P.*,Lan,H.X.*,Strom,A.,Macciotta,R. (2022). Landslide length,width and aspect ratio: path-dependent measurement and a revisit of nomenclature. Landslides,19,3009–3029.
30.Liu,S.J.,Lan,H.X.*,Martin,C.D. (2022). Progressive transition from extension fracture to shear fracture of altered granite during uniaxial tensile tests. Rock Mechanic and Rock Engineering,55,5355–5375.
31.Liu,X.,Lan,H.X.*,Li,L.P.*,Cui,P. (2022). An ecological indicator system for shallow landslide analysis. Catena,214,106211.
32.Liu,X.,Wang,L.*,Li,L.P.,Zhu,X.C.,Chang,C.Y.,Lan,H.X.* (2022). Optimum Phenological Phases for Deciduous Species Recognition: A Case Study on Quercus acutissima and Robinia pseudoacacia in Mount Tai. Forests,13(5),813.
33.Liu,X.*,Miao,X.Q.,Qin,Z.H.,Huang,G.J.,Lan,H.X.*,(2022). Shear behavior of loess: The role of drainage condition. Engineering Geology,309,106835.
34.Wu,Y.M.,Tian,A.H.,Lan,H.X.* (2022). Comparisons of Dynamic Landslide Models on GIS Platforms. Applied Sciences,12(6),3093.
35.Wu,Y.M.,Lan,H.X.* (2022). Study on the Deformation of Filling Bodies in a Loess Mountainous Area Based on InSAR and Monitoring Equipment. Land,11(8),1263.
36.Yao,J.M.,Lan,H.X.*,Li,L.P.,Cao,Y.M.,Wu,Y.M.,Zhang,Y.X.,Zhou,C.D. (2022). Characteristics of a rapid landsliding area along Jinsha River revealed by multi-temporal remote sensing and its risks to Sichuan-Tibet railway. Landslides,19,703–718.
37.Zhang,T.W.*,Hu,Z.J.,Lan,H.X.*,Deng,Y.F.,Zhang,H.Y. (2022). The compression behavior of undisturbed and compacted loess under the controlling of total suction and injected solutions. Frontiers in Earth Science,10,818919.
38.Zhou,C.D.,Lan,H.X.*,Bürgmann,R.,Warner,T.A.,Clague,J.J.,Li,L.P.,Wu,Y.M.,Zhao,X.X.,Zhang,Y.X.,Yao,J.M. (2022). Application of an improved multi-temporal InSAR method and forward geophysical model to document subsidence and rebound of the Chinese Loess Plateau following land reclamation in the Yan’an New District. Remote Sensing of Environment,279,113102.
39.Zhu,Y.B.*,Li,F.T.,Yang,F.F.,Zhang,Y.X.,Tian,W.H.,Lan,H.X.* (2022). Experimental investigation on failure modes and progressive failure process of earthen check dam triggered by upstream flow. Frontiers in Earth Science,10,818508.
40.Zhu,Y.B.*,Miao,S.S.,Li,H.F.,Han,Y.T.,Lan,H.X.* (2022). An Empirical Shear Model of Interface Between the Loess and Hipparion Red Clay in a Loess Landslide. Frontiers in Earth Science,9,806832.
41.Zhu,Y.B.*,Zheng,H.T.,Lan,H.X.*,Liu,Y.W.,Li,L.P.,Fu,B.Y.,Du,C.C. (2022). Effect of initial water content and dry density on the self-healing of desiccation cracks in compacted hipparion red clay. Frontiers in Earth Science,10,963086.
42.Chen,J.H.,Lan,H.X.*,Macciotta,R.,Martin,C.D.,& Wu,Y.M. (2021). Microfracture characterization of shale constrained by mineralogy and bedding. Journal of Petroleum Science and Engineering,201,108456.
43.Lan,H.X.*,Zhao,X.X.,Macciotta,R.*,Peng,J.B.,Li,L.P.,Wu,Y.M.,Zhu,Y.B.,Liu,X.,Zhang,N.,Liu,S.J.,Zhou,C.H.,Clague,J.J. (2021). The cyclic expansion and contraction characteristics of a loess slope and implications for slope stability. Scientific Reports,11,2250.
44.Liu,X.*,Zhang,W.Z.,Wei,X.,& Lan,H.X.*. (2021). Unified characterization of hydro-mechanical properties of soil-bentonite mixtures exposed to pore-fluid salinity. Journal of Zhejiang University-SCIENCEA,22(3),188-194.
45.Bao,H.,Qi,Q.,Lan,H.X.*,Yan,C.G.,Feng,L.,Xu,J.B.,Yin,P.J. (2020). Sliding mechanical properties of fault gouge studied from ring shear test-based microscopic morphology characterization. Engineering Geology,279,105879.
46.Bao,H.,Xu,X.H.*,Lan,H.X.*,Zhang,G.B.,Yin,P.J.,Yan,C.G.,Xu,J.B. (2020). A new joint morphology parameter considering the effects of micro-slope distribution of joint surface. Engineering Geology,275,105734.
47.Bao,H.,Zhang,G.B.,Lan,H.X.*,Yan,C.G.,Xu,J.B.,Xu,W. (2020). Geometrical heterogeneity of the joint roughness coefficient revealed by 3D laser scanning. Engineering Geology,265,105415.
48.Li,L.P.,Lan,H.X.*,Peng,J.B. (2020). Loess erosion patterns on a cut-slope revealed by LiDAR scanning. Engineering Geology,268,105516.
49.Li,L.P.,Lan,H.X.*,Strom,A. (2020). Automatic generation of landslide profile for complementing landslide inventory. Geomatics,Natural Hazards and Risk,11(1),1000–1030.
50.Liu,X.*,Tian,C.Y.,Lan,H.X.* (2020). Laboratory investigation of the mechanical properties of a rubber–calcareous sand mixture: the effect of rubber content. Applied Sciences,10(18),6583.
51.Wu,Y.M.,Lan,H.X.* (2020). Debris Flow Analyst (DA):A debris flow model considering kinematic uncertainties and using a GIS platform,Engineering Geology,279,105877.
52.Zhang,Y.X.,Lan,H.X.*,Li,L.P.,Wu,Y.M.,Chen,J.H.,Tian,N.M..(2020). Optimizing the frequency ratio method for landslide susceptibility assessment: A case study of the Caiyuan Basin in the southeast mountainous area of China. Journal of Mountain Science,17(2),340–357.
53.Zhao,X.X.,Lan,H.X.*,Li,L.P.,Zhang,Y.X.,Zhou,C.D. (2020). A Multiple-Regression Model Considering Deformation Information for Atmospheric Phase Screen Compensation in Ground-Based SAR. IEEE Transactions on Geoscience and Remote Sensing,58(2),777–789.
54.Zhou,C.D.,Lan,H.X.*,Gong,H.L.,Zhang,Y.Q.,Warner,T.A.,Clague,J.J.,Wu,Y.M. (2020). Reduced rate of land subsidence since 2016 in Beijing,China: evidence from Tomo-PSInSAR using RadarSAT-2 and Sentinel-1 datasets. International Journal of Remote Sensing,41(4),1259–1285.
55.Lan,H.X.*,Chen,J.H.,Macciotta R. (2019). Universal Confined Tensile Strength of Intact Rock. Scientific Reports,9,6170.
56.Li,L.P.,Lan,H.X.* (2019). Recovering absolute scale for Structure from Motion using the law of free fall. Optics and Laser Technology,112,514–523.
57.Li,Q.W.,Lan,H.X.*,Zhao,X.X.,Wu,Y.M. (2019). River centerline extraction using the multiple direction integration algorithm for mixed and pure water pixels. Giscience & Remote Sensing,56(2),256–281.
58.Liu,X.,Zhang,N.,Lan,H.X.*,2019. Effects of sand and water contents on the small-strain shear modulus of loess. Engineering Geology,260(3),105202.
59.Wu,Y.M.,Lan,H.X.* (2019). Landslide Analyst — a landslide propagation model considering block size heterogeneity. Landslides,16,1107–1120.
60.Zhang,F.Y.*,Yan,B.B.,Feng,X.M.,Lan,H.X.*,Kang,C.,Lin,X.S.,Zhu,X.H.,Ma,W.G. (2019). A rapid loess mudflow triggered by the check dam failure in a bulldoze mountain area,Lanzhou,China. Landslides,16,1981–1992.
61.Chen,J.H.,Lan,H.X.*,Macciotta,R.,Wu,Y.M,Li,Q.W.,Zhao,X.X. (2018). Anisotropy rather than transverse isotropy in Longmaxi shale and the potential role of tectonic stress. Engineering Geology,247,38–47.
62.Li,L.P.,Lan,H.X.*,Guo,C.B.,Zhang,Y.S.,Li,Q.W.,Wu,Y.M. (2017). A modified frequency ratio method for landslide susceptibility assessment. Landslides,14(2),727–741.
63.Li,L.P.,Lan,H.X.*,Wu,Y.M. (2016). How sample size can effect landslide size distribution. Geoenvironmental Disasters,3,18.
64.Li,L.P.,Lan,H.X.* (2015). Probabilistic modeling of rockfall trajectory: a review. Bulletin of Engineering Geology and the Environment,74,1163–1176.
65.Meng,Y.S.,Lan,H.X.*,Li,L.P.,Wu,Y.M.,Li,Q.W. (2015). Characteristics of Surface Deformation Detected by X-band SAR Interferometry over Sichuan-Tibet Grid Connection Project Area,China. Remote Sensing,7(9),12265–12281.
66.Wu,Y.M.,Lan,H.X.*,Gao,X.,Li,L.P.,Yang,Z.H. (2015). A simplified physically based coupled rainfall threshold model for triggering landslides. Engineering Geology,195,63–69.
67.Yang,Z.H.,Lan,H.X.*,Gao,X.,Li,L.P.,Meng,Y.S.,Wu,Y.M. (2015). Urgent Landslide Susceptibility Assessment in the 2013 Lushan Earthquake-impacted Area,Sichuan province,China. Natural Hazards,75,2467–2487.
68.Yang,Z.H.,Lan,H.X.*,Liu,H.J.,Li,L.P.,Wu,Y.M. Meng,Y.S,Xu,L. (2015). Post-earthquake Rainfall-triggered Slope Stability Analysis in The Lushan Area. Journal of Mountain Science,12(1),232–242.
69.Li,L.P.,Lan,H.X.*,Wu,Y.M. (2014). The volume-to-surface-area ratio constrains the rollover of the power law distribution for landslide size. The European Physical Journal Plus,129(5),89.
70.Lan,H.X.*,Gao,X.,Liu,H.J.,Yang,Z.H.,Li,L.P. (2013). Integration of TerraSAR-X and PALSAR PSI for detecting ground deformation. International Journal of Remote Sensing,34(15),5393–5408.
71.Lan,H.X.*,Li,L.P.,Zhang,Y.S.,Gao,X.,Liu,H.J. (2013). Risk assessment of debris flow in Yushu seismic area in China: a perspective for the reconstruction. Natural Hazards and Earth System Sciences,13(11),2957–2968.
72.Lan,H.X.*,Martin,C.D.,Andersson,J.C. (2013). Evolution of in situ rock mass damage induced by mechanical-thermal loading. Rock Mechanics and Rock Engineering,46(1),153–168.
73.Yang,Z.H.,Lan,H.X.*,Zhang,Y.S.,Gao,X.,Li,L.P. (2013). Nonlinear dynamic failure process of tunnel-fault system in response to strong seismic event. Journal of Asian Earth Sciences,64,125–135.
74.Lan,H.X.*,Li,L.P.,Liu,H.J.,Yang,Z.H. (2012). Complex urban infrastructure deformation monitoring using high resolution PSI. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing,5(2),643–651.
75.Li,L.P.,Lan,H.X.*,Wu,Y.M. (2012). Comment on"Statistical physics of landslides: New paradigm"by Chen C.-c. et al..EPL (Europhysics Letters),100,29001.
76.Liu,H.J.,Lan,H.X.*,Liu,Y.,Zhou,Y. (2011). Characteristics of spatial distribution of debris flow and the effect of their sediment yield in main downstream of Jinsha River,China. Environmental Earth Sciences,64(6),1653–1666.
77.Lan,H.X.*,Martin,C.D.,Hu,B. (2010). Effect of heterogeneity of brittle rock on micromechanical extensile behavior during compression loading. Journal of Geophysical Research,115(B1),B01202.
78.Lan,H.X.*,Martin,C.D.,Zhou,C.H.,Lim,C.H. (2010). Rockfall hazard analysis using LiDAR and spatial modeling. Geomorphology,118(1-2),213–223.
79.Lan,H.X.*,Martin,C.D.,Froese,C.R.,Kim,T.H.,Morgan,A.J.,Chao,D.,Chowdhury,S. (2009). A web-based GIS for managing and assessing landslide data for the town of Peace River,Canada. Natural Hazards and Earth System Sciences,9(4),1433–1443.
80.Lan,H.X.*,Martin,C.D.,Zhou,C.H. (2008). Estimating the size and travel distance of Klapperhorn Mountain debris flows for risk analysis along railway,Canada. International Journal of Sediment Research,23(3),275–282.
81.Lan,H.X.,Martin,C.D.*,Lim,C.H. (2007). RockFall analyst: A GIS extension for three-dimensional and spatially distributed rockfall hazard modeling. Computers & Geosciences,33(2),262–279.
82.Lan,H.X.*,Lee,C.F.,Zhou,C.H.,Martin,C.D. (2005). Dynamic characteristics analysis of shallow landslides in response to rainfall event using GIS. Environmental Geology,47(2),254–267.
83.Lan,H.X.*,Zhou,C.H.,Wang,L.J.,Zhang,H.Y.,Li,R.H. (2004). Landslide hazard spatial analysis and prediction using GIS in the Xiaojiang watershed,Yunnan,China. Engineering Geology,76(1-2),109–128.
84.Lan,H.X.*,Hu,R.L.,Yue,Z.Q.,Lee,C.F.,Wang,S.J. (2003). Engineering and geological characteristics of granite weathering profiles in South China. Journal of Asian Earth Sciences,21(4),353–364.
85.Lan,H.X.*,Wu,F.Q.,Zhou,C.H.,Wang,L.J. (2003). Spatial hazard analysis and prediction on rainfall-induced landslide using GIS. Chinese Science Bulletin,48(7),703–708.
86.Lan,H.X.*,Zhou,C.H.,Lee,C.F.,Wang,S.J.,Wu,F.Q. (2003). Rainfall-induced landslide stability analysis in response to transient pore pressure - A case study of natural terrain landslide in Hong Kong.SCIENCECHINA Technological Sciences,46(s1),52–68.
87.劉鑫,蘭恒星*,晏長根,董忠紅,包含,伍宇明,張帆宇,祝艷波,張軍(2023). 鉆孔原位剪切測試系統研制及應用. 交通運輸工程學報.
88.王小嬋,蘭恒星*,劉世杰,孫巍鋒 (2024). 考慮細觀顆粒破損的粒狀材料彈塑性本構模型研究. 巖土工程學報.
89.陳釗,蘭恒星*,劉世杰,都奎建 (2024). 干濕循環作用下石窟砂巖的抗拉強度劣化機理及破壞模式. 地球科學,49(2),612–624.
90.都奎建,蘭恒星*,劉世杰,包含,李黎 (2024). 石窟寺砂巖階段異質性劣化特征與損傷機制研究. 工程地質學報,32(6),1951–1962.
91.孫巍鋒,蘭恒星*,包含,田朝陽,晏長根 (2024). Ms6.8 級瀘定地震作用下大渡河工程邊坡變形響應分析. 工程地質學報,32(5),1654–1668.
92.許博聞,蘭恒星*,劉世杰 (2024). 界面形態對黃土-泥巖接觸面剪切力學特性影響研究. 工程地質學報,32(2),448–462.
93.蘭恒星,呂洪濤,包含*,李黎,陳衛昌,郭進京,劉世杰 (2023). 石窟寺巖體劣化機制與失穩機理研究進展. 地球科學,48(4),1603–1633.
94.劉鑫,蘭恒星*,晏長根,董忠紅,包含,伍宇明,張帆宇,祝艷波,張軍(2023). 鉆孔原位剪切測試系統設計. 交通運輸工程學報,23(4),154–164.
95.張文哲,蘭恒星*,劉鑫 (2023). 鹽溶液對石英粉-膨潤土混合土滲透系數的影響與表征. 工程地質學報,31(1),90–101.
96.蘭恒星,彭建兵*,祝艷波,李郎平,潘保田,黃強兵,李軍華,張強 (2022). 黃河流域地質地表過程與重大災害效應研究與展望. 中國科學:地球科學,52(2),199–221.
97.蘭恒星*,包含,孫巍鋒,劉世杰 (2022). 巖體多尺度異質性及其力學行為. 工程地質學報,30(1),37–52.
98.李郎平,蘭恒星* (2022). 滑坡運動路徑復雜度研究:綜述與展望. 地球科學,47(12),4663–4680.
99.劉世杰,蘭恒星*,包含,彭建兵 (2022). 石窟寺典型工程地質變形破壞模式及分類體系. 地球科學,47(12),4710–4723.
100.劉世杰,蘭恒星*,張寧 (2022). 嘉黎斷裂中段重大工程區地質力學分析. 工程地質學報,30(6),1947–1961.
101.田朝陽,蘭恒星*,張寧,許博聞 (2022). 某交通線路色季拉山隧道高地應力巖爆風險定量預測研究. 工程地質學報,30(3),621–634.
102.王瑞,蘭恒星*,劉世杰,伍宇明 (2022). 火災對于巖土體物理力學特性的影響研究. 地球科學與環境學報,44(1),114–123.
103.袁逸齊,蘭恒星*,劉世杰,姚佳明,孫巍鋒,包含,李黎 (2022). 砂巖石窟熱誘導裂紋損傷時空特征與分析. 巖石力學與工程學報,41(12),2530–2542.
104.張寧,蘭恒星*,李郎平,孫巍鋒,劉世杰,林感,田朝陽 (2022). 青藏高原東南緣實測地應力特征及意義分析. 工程地質學報,30(3),696–707.
105.張寧,張文哲,李郎平,蘭恒星* (2022). 青藏高原地溫時空分布及某重大線性工程深部高地溫風險分析. 工程地質學報,30(3),708–719.
106.蘭恒星*,張寧,李郎平,田乃滿,仉義星,劉世杰,林感,田朝陽,伍宇明,姚佳明,彭建兵,周成虎 (2021). 川藏鐵路可研階段重大工程地質風險分析. 工程地質學報,29(2),326–341.
107.蘭恒星*,祝艷波,李郎平,潘保田,胡振波,彭建兵 (2021). 黃河流域地質-地貌-氣候多過程相互作用及其孕災機制研究. 中國科學基金,35(4),510–519.
108.田朝陽,蘭恒星*,劉鑫 (2021). 考慮形貌特征和級配影響的鈣質砂壓縮破碎力學特性研究. 工程地質學報,29(6),1700–1710.
109.伍宇明,蘭恒星*,黃為清 (2021). 不飽和黃土的波速與質量含水率關系. 地球物理學報,64(10),3766–3773. (SCI)
110.祝艷波,蘭恒星*,彭建兵,李軍華,張攀,張彤煒,朱興華,張亞國,劉鑫,谷天峰,李郎平 (2021). 黃河中游地區水土災害機理與災害鏈效應研究進展. 人民黃河,43(8),108–116,147.
111.田乃滿,蘭恒星*,伍宇明,李郎平 (2020). 人工神經網絡和決策樹模型在滑坡易發性分析中的性能對比. 地球信息科學學報,22(12),2304–2316.
112.伍宇明,蘭恒星*,黃為清 (2020). 龍馬溪頁巖彈性各向異性與礦物分布之間的關系探討. 地球物理學報,63(5),1856–1866. (SCI)
113.蘭恒星*,孟云閃,仉義星 (2019). 復雜因素影響下的福州市地面沉降時空演化分析. 工程地質學報,27(6),1350–1361.
114.蘭恒星*,仉義星,伍宇明 (2019). 巖體結構效應與長遠程滑坡動力學. 工程地質學報,27(1),108–122.
115.仉義星,蘭恒星*,李郎平,伍宇明,陳志超,陳俊輝 (2019). 綜合統計模型和物理模型的地質災害精細評估——以福建省龍山社區為例. 工程地質學報,27(3),608–622.
116.蘭恒星*,陳俊輝,伍宇明 (2018). 三軸壓縮試驗前后含氣頁巖微納尺度裂隙空間分布特征研究. 工程地質學報,26(1),24–35.
117.蘭恒星*,伍宇明,李全文,陳俊輝,趙曉霞 (2017). 龍馬溪組頁巖三維縫網重構及分形分析. 工程地質學報,25(6),1557–1565.
118.蘭恒星*,趙曉霞,伍宇明,李郎平,蘇奮振 (2017). 鈣質島礁沉降變形過程分析. 中國海洋大學學報(自然科學版),47(10),1–8.
119.李郎平,蘭恒星*,郭長寶,張永雙,李全文,伍宇明 (2017). 基于改進頻率比法的川藏鐵路沿線及鄰區地質災害易發性分區評價. 現代地質,31(5),911–929.
120.蘭恒星*,肖銳鏵,嚴福章,伍宇明 (2016). 川藏聯網工程地質條件分析. 工程地質學報,24(Suppl.),375–385.
121.伍法權,蘭恒星* (2016). 國際工程地質與環境研究現狀及前沿——第十二屆國際工程地質大會(IAEG XII)綜述. 工程地質學報,24(1),116–129.
122.伍宇明,蘭恒星*,高星,李郎平 (2014). 臺風暴雨型滑坡降雨閾值曲線研究——以福建地區為例. 工程地質學報,22(2),255–262.
123.伍宇明,蘭恒星*,高星,李郎平,孟云閃 (2014). 一種基于Bayes理論的區域斜坡穩定性評價模型. 工程地質學報,22(6),1227–1233.
124.蘭恒星*,周成虎,高星,程維明,王治華,楊志華,李郎平,伍宇明 (2013). 四川雅安蘆山地震災區次生地質災害評估及對策建議. 地理科學進展,32(4),499–504.
125.楊志華,蘭恒星*,張永雙,李郎平,熊探宇 (2013). 強震作用下穿越斷層隧道圍巖力學響應研究. 工程地質學報,21(2),171–181.
126.蘭恒星*,劉洪江,孫鐵,賈有良,楊志華,丁尚起,黃曉明 (2012). 城市建筑物沉降永久散射體干涉雷達監測. 天津大學學報,45(4),292–300. (EI)
127.李郎平,蘭恒星*,李曉,孟云閃,陳雨 (2012). 金壇鹽穴天然氣儲庫區地表變形PSI監測. 巖石力學與工程學報,31(9),1821–1829. (EI)
128.劉洪江,蘭恒星* (2012).“5.12"震后都江堰-汶川公路崩塌災害模擬及危險性評價. 資源科學,34(2),345–352.
129.楊志華,蘭恒星*,張永雙 (2012). 基于GIS-GOCAD耦合技術的三維地質建模. 地理與地理信息科學,28(5),16–20.
130.蘭恒星*,劉洪江,孫鐵,賈有良,楊志華,李郎平,丁尚起,黃曉明 (2011). 城市復雜地面沉降永久干涉雷達監測屬性分類研究. 工程地質學報,19(6),893–901.
131.劉洪江,蘭恒星*,程維明 (2010). 玉樹地震后結古鎮群發式泥石流災害數值模擬及危險性分析. 山地學報,28(4),444–452.
132.劉洪江,蘭恒星*,張軍,劉杰,楊軍 (2010). 老撾北部罌粟替代種植高分辨率遙感調查評價與分析. 資源科學,32(7),1425–1432.
133.蘭恒星*,周成虎,王小波 (2007). 泥石流本構模型及動力學模擬研究現狀綜述. 工程地質學報,15(3),314–321.
134.蘭恒星*,王苓涓,周成虎 (2003). 云南小江流域滑坡關鍵影響因子研究. 中國地質災害與防治學報,14(1),100–106.
135.蘭恒星*,伍法權,周成虎,王苓涓 (2003). GIS支持下的降雨型滑坡危險性空間分析預測. 科學通報,48(5),507–512.
136.蘭恒星*,周成虎,李焯芬,王思敬,伍法權 (2003). 瞬時孔隙水壓力作用下的降雨滑坡穩定性響應分析:以香港天然降雨滑坡為例. 中國科學E輯-技術科學,33(增刊),119–136.
137.蘭恒星*,周成虎,王苓涓,伍法權,王思敬 (2003). 地理信息系統支持下的滑坡-水文耦合模型研究. 巖石力學與工程學報,22(8),1309–1314. (EI)
138.蘭恒星*,王苓涓,周成虎 (2002). 地理信息系統支持下的滑坡災害分析模型研究. 工程地質學報,10(4),421–427.
139.蘭恒星*,伍法權,王思敬 (2002). 基于GIS的滑坡CF多元回歸模型及其應用. 山地學報,20(6),732–737.
140.蘭恒星*,伍法權,周成虎,王思敬 (2002). 基于GIS的滑坡空間數據庫研究—以云南小江流域為例. 中國地質災害與防治學報,13(4),10–16.
141.蘭恒星*,伍法權,周成虎,王思敬 (2002). 基于GIS的云南小江流域滑坡因子敏感性分析. 巖石力學與工程學報,21(10),1500–1506. (EI)
142.蘭恒星*,祁生文,伍法權 (2001). 溪洛渡水電站干海子滑坡非線性動力學模擬. 湘潭礦業學院學報,16(3),5–10. (EI)
143.蘭恒星*,伍法權 (2001). 巖土力學數值模擬中力學參數的確定方法. 世界地質,20(1),66–71.
144.蘭恒星*,李增學,魏久傳 (2000). 山東黃縣早第三紀斷陷盆地充填演化動力學特征. 煤田地質與勘探,28(2),6–10.
145.蘭恒星*,伍法權 (2000). 基于條分法的滑坡位移非線性動力學模擬方法. 工程地質學報,8(3),374–378.
研究生招生與培養:
招生專業:地圖學與地理信息系統
招生方向:地理信息系統與自然災害
聯系方式:
通訊地址:北京市朝陽區大屯路甲11號 中國科學院地理科學與資源研究所
郵 ???編:100101
辦公電話:010-64888783
傳 ???真:010-64889630
E-mail地址:lanhx@igsnrr.ac.cn;lanhx@lreis.ac.cn
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