2016


  1. Bièvre G., Jongmans D., Goutaland D., Pathier E. and Zumbo V. 2016. Geophysical characterization of the lithological control on the kinematic pattern in a large clayey landslide (Avignonet, French Alps). Landslides, 13(3):423–436. PDF, DOI

  2. Fernandez P. and Whitworth M. 2016. A new technique for the detection of large scale landslides in glacio-lacustrine deposits using image correlation based upon aerial imagery: A case study from the French Alps. International Journal of Applied Earth Observation and Geoinformation, 52:1–11. PDF, DOI

 

2015


  1. Mainsant G., Chambon G., Jongmans D., Larose E. and B. Laurent 2015. Shear-wave-velocity drop prior to clayey mass movement in laboratory flume experiments. Engineering Geology, 192:26–32. PDF, DOI

  2. OMIV. 2006. National French Landslide Observatory Facility and RESIF Datacenter: French Multidisciplinary Observatory of Versant Instabilities. RESIF - Réseau Sismologique et géodésique Français. Seismic Network. DOI

 

< 2014


  1. Van der Spek J.-E., Bogaard T.-A. and Bakker M. 2013. Characterization of groundwater dynamics in landslides in varved clays. Hydrology and Earth System Sciences, 17(6):2171-2183. PDF, DOI

  2. Bièvre G., Jongmans D., Winiarski T. and Zumbo V. 2012. Application of geophysical measurements for assessing the role of fissures in water infiltration within a clay landslide (Trièves area, French Alps). Hydrological Processes, 26(14):2128-2142. PDF, DOI

  3. Malet J.-P. and Bogaard T. A. 2012. Integration of technologies for landslide monitoring and quantitative hazard assessment. Engineering Geology, 128:1. PDF, DOI

  4. Mainsant G., Jongmans D., Chambon G., Larose E. and Baillet L. 2012. Shear-wave velocity as an indicator for rheological changes in clay materials: Lessons from laboratory experiments. Geophysical research letters, 39(L19301). PDF, DOI

  5. Bièvre G., Kniess U., Jongmans D., Pathier E., Schwartz S., van Westen C. J., Villemin T. and Zumbo V. 2011. Paleotopographic control of landslides in lacustrine deposits (Trièves plateau, French western Alps). Hydrological processes, 125(1):214-224. PDF, DOI

  6. Renalier F., Bièvre G., Jongmans D. and Campillo M.and Bard P.-Y. 2010. Shear wave velocity imaging of the Avignonet landslide (France) using ambient noise cross correlation. Journal of Geophysical Research, 115(F03032):1-14. PDF, DOI

  7. Jongmans D., Bièvre G., Schwartz S., Renalier F., Beaurez N. and Y. Orengo 2009. Geophysical investigation of a large landslide in glaciolacustrine clays in the Trièves area (French Alps). Engineering geology, 109(1):45–56. PDF, DOI

  8. Leone F., Asté J.-P. and Leroi E. 1996. L'évaluation de la vulnérabilité aux mouvements de terrains: pour une meilleure quantification du risque. , 84(1):35-46. PDF, DOI

  9. Antoine P., Monnet J., Rai N.-E., Moulin C. and Meriaux P. 1991. Résultats de cinq années d'auscultation sur un glissement dans les argiles glacio-lacustres du Trièves (Sud-Est de la France). , p.1-8. PDF

  10. Giraud A., Antoine A., Van Asch T. W. J. and Nieuwenhuis J. D. 1991. Geotechnical problems caused by glaciolacustrine clays in the French Alps. Engineering geology, 31(1):185-195. PDF, DOI

  11. Al Hayari M., Antoine P., Biguenet G., Monnet J. and More H. 1990. Détermination des caractéristiques mécaniques au cisaillement des argiles litées, Cas du glissement de la combe d'Harmalière. Revue Française de Géotechnique, 50:71–77. PDF

  12. Antoine P., Giraud A. and Montjuvent G. 1981. Les argiles litées du Trièves (Isère), conditions de gisement et exemples de propriétés géotechniques. Bulletin de la Société Géologique de France, 7(2):117-127. DOI