研究員
蘭恒星
文章來源: | 發(fā)布時間:2016-09-09 | 【打印】 【關(guān)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(shù)全國重點實驗室研究員、博士生導師。
????目前任國際工程地質(zhì)與環(huán)境協(xié)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(zhì)科學技術(shù)獎等獎項。
研究領(lǐng)域與研究方向:
主要從事多尺度巖土體變形破壞機理、環(huán)境與地質(zhì)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(zhì)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(jīng)歷:(倒序排列)
2009-04~現(xiàn)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(huán)境信息系統(tǒng)國家重點實驗室,博士后
科研業(yè)績:
????主要從事巖土體變形破壞機理、地質(zhì)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(fā)表學術(shù)論文300余篇,其中SCI檢索論文150余篇,授權(quán)專利50余項。
????近年來主要學術(shù)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(lǐng)先;創(chuàng)建了集成GIS系統(tǒng)的三維分布式地質(zhì)災害動力學過程模型,在全球40個國家的學術(shù)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(lǐng)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(zhì)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(jié)構(gòu)黃土邊坡工程地質(zhì)自適應原位協(xié)同探測系統(tǒng),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(zhì)動力學與地質(zhì)災害,2016/01 ~ 2020/12,主持
國家自然科學基金委員會,創(chuàng)新研究群體項目,項目:地理時空數(shù)據(jù)分析—子課題:地表過程大數(shù)據(jù)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(jiān)測模型及技術(shù),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(guī)模與關(guān)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(qū)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(huán)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(shù)部,國家重點研發(fā)計劃項目課題,項目:石窟寺巖體穩(wěn)定性預測及加固技術(shù)研究—課題一:卸荷帶石窟寺巖體耦合松動機制與失穩(wěn)機理,2020/01 ~ 2022/12,主持
科學技術(shù)部,第二次青藏高原綜合科學考察研究子專題,任務九:地質(zhì)環(huán)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(qū)重大工程擾動災害及風險,2019/11 ~ 2022/10,主持
科學技術(shù)部,國家重點基礎研究發(fā)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(qū)底層變形機理與地面沉降監(jiān)測,2009/01 ~ 2013/12,參加
科學技術(shù)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(shù)研究—課題五:承險過程分析與承險脆弱性綜合評估技術(shù),2008/09 ~ 2011/12,參加
中國科學院,中國科學院戰(zhàn)略性先導科技專項(A類)子課題,專項:美麗中國生態(tài)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(diào)控關(guān)鍵技術(shù)與示范—課題三:山地致災風險定量評估關(guān)鍵技術(shù)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(gòu)建,2019/01 ~ 2023/12,主持
中國科學院,中國科學院戰(zhàn)略性先導科技專項(A類)子課題,專項:地球大數(shù)據(jù)科學工程—項目四:全景美麗中國—課題三:“三生”空間統(tǒng)籌優(yōu)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(zhì)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(jiān)測與機理分析,2016/08 ~ 2021/07,參加
中科院STS項目課題,魯?shù)榈卣馂暮笾亟ǖ牡刭|(zhì)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(zhàn)略性先導科技專項(B類)課題,專項:頁巖氣勘探開發(fā)基礎理論與關(guān)鍵技術(shù)—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(zhì)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(zhì)災害風險應對戰(zhàn)略研究—課題一:瓊東南盆地海底地質(zhì)災害防控對策戰(zhàn)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(jīng)濟區(qū)(閩江、九龍江等流域)生態(tài)環(huán)境安全與可持續(xù)發(fā)展研究—課題四:海西經(jīng)濟區(qū)地質(zhì)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.
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92.許博聞,蘭恒星*,劉世杰 (2024). 界面形態(tài)對黃土-泥巖接觸面剪切力學特性影響研究. 工程地質(zhì)學報,32(2),448–462.
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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(tǒng)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(shù)的影響與表征. 工程地質(zhì)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(zhì)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(zhì)性及其力學行為. 工程地質(zhì)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(zhì)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(qū)地質(zhì)力學分析. 工程地質(zhì)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(zhì)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(huán)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(zhì)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(zhì)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(zhì)風險分析. 工程地質(zhì)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(zhì)-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(zhì)砂壓縮破碎力學特性研究. 工程地質(zhì)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(zhì)量含水率關(guān)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(qū)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(jīng)網(wǎng)絡和決策樹模型在滑坡易發(fā)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(guān)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(zhì)學報,27(6),1350–1361.
114.蘭恒星*,仉義星,伍宇明 (2019). 巖體結(jié)構(gòu)效應與長遠程滑坡動力學. 工程地質(zhì)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(tǒng)計模型和物理模型的地質(zhì)災害精細評估——以福建省龍山社區(qū)為例. 工程地質(zhì)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(zhì)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(wǎng)重構(gòu)及分形分析. 工程地質(zhì)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(zhì)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(qū)地質(zhì)災害易發(fā)性分區(qū)評價. 現(xiàn)代地質(zhì),31(5),911–929.
120.蘭恒星*,肖銳鏵,嚴福章,伍宇明 (2016). 川藏聯(lián)網(wǎng)工程地質(zhì)條件分析. 工程地質(zhì)學報,24(Suppl.),375–385.
121.伍法權(quán),蘭恒星* (2016). 國際工程地質(zhì)與環(huán)境研究現(xiàn)狀及前沿——第十二屆國際工程地質(zhì)大會(IAEG XII)綜述. 工程地質(zhì)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(qū)為例. 工程地質(zhì)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(qū)域斜坡穩(wěn)定性評價模型. 工程地質(zhì)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(qū)次生地質(zhì)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(zhì)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(jiān)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(qū)地表變形PSI監(jiān)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(shù)的三維地質(zhì)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(jiān)測屬性分類研究. 工程地質(zhì)學報,19(6),893–901.
131.劉洪江,蘭恒星*,程維明 (2010). 玉樹地震后結(jié)古鎮(zhèn)群發(fā)式泥石流災害數(shù)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(diào)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(gòu)模型及動力學模擬研究現(xiàn)狀綜述. 工程地質(zhì)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(guān)鍵影響因子研究. 中國地質(zhì)災害與防治學報,14(1),100–106.
135.蘭恒星*,伍法權(quán),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(quán) (2003). 瞬時孔隙水壓力作用下的降雨滑坡穩(wěn)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(shù)科學,33(增刊),119–136.
137.蘭恒星*,周成虎,王苓涓,伍法權(quán),王思敬 (2003). 地理信息系統(tǒng)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(tǒng)支持下的滑坡災害分析模型研究. 工程地質(zhì)學報,10(4),421–427.
139.蘭恒星*,伍法權(quán),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(quán),周成虎,王思敬 (2002). 基于GIS的滑坡空間數(shù)據(jù)庫研究—以云南小江流域為例. 中國地質(zhì)災害與防治學報,13(4),10–16.
141.蘭恒星*,伍法權(quán),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(quán) (2001). 溪洛渡水電站干海子滑坡非線性動力學模擬. 湘潭礦業(yè)學院學報,16(3),5–10. (EI)
143.蘭恒星*,伍法權(quán) (2001). 巖土力學數(shù)值模擬中力學參數(shù)的確定方法. 世界地質(zhì),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(zhì)與勘探,28(2),6–10.
145.蘭恒星*,伍法權(quán) (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(zhì)學報,8(3),374–378.
研究生招生與培養(yǎng):
招生專業(yè):地圖學與地理信息系統(tǒng)
招生方向:地理信息系統(tǒng)與自然災害
聯(lián)系方式:
通訊地址:北京市朝陽區(qū)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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