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The Energetics of Snow Avalanche Motion
Bartelt, P., Buser, O., & Bugnion, L. (2008). The Energetics of Snow Avalanche Motion. In Proceedings International Workshop on Snow, Ice, Glacier and Avalanches (pp. 267-275). Indian Institute of Technology.
Modeling rockfall trajectories with non-smooth contact/impact mechanics
Bartelt, P., Gerber, W., Christen, M., & Bühler, Y. (2016). Modeling rockfall trajectories with non-smooth contact/impact mechanics. In G. Koboltschnig (Ed.), 13th congress INTERPRAEVENT 2016. 30 May to 2 June 2016. Lucerne, Switzerland. Conference proceedings "Living with natural risks" (pp. 203-211).
The SFISAR quasi two-dimensional model
Bartelt, P., & Gruber, U. (1998). The SFISAR quasi two-dimensional model. In C. B. Harbitz (Ed.), Norwegian Geotechnical Institute report. SAME Snow Avalanche Modelling, Mapping, and Warning in Europe (pp. 39-42).
Work minimisation in rock and snow avalanches: The competition between random kinetic energy and heat
Bartelt, P., Buser, O., & Platzer, K. (2007). Work minimisation in rock and snow avalanches: The competition between random kinetic energy and heat. In Proc. 1. Departementkongress Bautechnik und Naturgefahren (p. 7).
Triaxial creep tests on snow and a new microstructure-based snow viscosity law
Bartelt, P., & von Moos, M. (2000). Triaxial creep tests on snow and a new microstructure-based snow viscosity law. In E. Hjorth-Hansen, I. Holand, S. Løset, & H. Norem (Eds.), Snow engineering. Recent advances and developments. Proceedings of the fourth international conference on snow engineering (pp. 23-31). Balkema.
A short comparison between Voellmy-fluid and Criminale-Ericksen-Filby-fluid dense snow avalanche models
Bartelt, P., & Salm, B. (1998). A short comparison between Voellmy-fluid and Criminale-Ericksen-Filby-fluid dense snow avalanche models. In E. Hestnes (Ed.), NGI Publication: Vol. 203. 25 Years of Snow Avalanche Research at NGI, proceedings anniversary conference (pp. 65-69).
A finite element snowpack model
Bartelt, P., & Ammann, W. (1999). A finite element snowpack model. In E. G. Prater (Ed.), Festschrift zum 60. Geburtstag von Prof. Dr. Edoardo Anderheggen (pp. 49-55). Institut für Baustatik und Konstruktion, ETH.
Program Haefeli - Two-dimensional numerical simulation of the creeping deformation and temperature distribution in a phase changing snowpack
Bartelt, P., Christen, M., & Wittwer, S. (2000). Program Haefeli - Two-dimensional numerical simulation of the creeping deformation and temperature distribution in a phase changing snowpack. In E. Hjorth-Hansen, I. Holand, S. Løset, & H. Norem (Eds.), Snow engineering. Recent advances and developments. Proceedings of the fourth international conference on snow engineering (pp. 13-22). Balkema.
Reply to "Discussion of "The relation between dilatancy, effective stress and dispersive pressure in granular avalanches" by P. Bartelt and O. Buser (DOI: 10.1007/s11440-016-0463-7)" by Richard Iverson and David L. George (DOI: 10.1007/s11440-016-0502-4)
Bartelt, P., & Buser, O. (2016). Reply to "Discussion of "The relation between dilatancy, effective stress and dispersive pressure in granular avalanches" by P. Bartelt and O. Buser (DOI: 10.1007/s11440-016-0463-7)" by Richard Iverson and David L. George (DOI: 10.1007/s11440-016-0502-4). Acta Geotechnica, 11(6), 1469-1473. https://doi.org/10.1007/s11440-016-0503-3
Numerical simulation of snow avalanches: modelling dilatative processes with cohesion in rapid granular shear flows
Bartelt, P., Buser, O., Bühler, Y., Dreier, L., & Christen, M. (2014). Numerical simulation of snow avalanches: modelling dilatative processes with cohesion in rapid granular shear flows. In M. A. Hicks, R. B. J. B. Brinkgreve, & A. Rohe (Eds.), Numerical Methods in Geotechnical Engineering - Proceedings (pp. 327-332). CRC Press.
Avalanche physics ploughs ahead
Bartelt, P., & Buser, O. (2001). Avalanche physics ploughs ahead. Physics World (March 2001), 25-29.
The relation between dilatancy, effective stress and dispersive pressure in granular avalanches
Bartelt, P., & Buser, O. (2016). The relation between dilatancy, effective stress and dispersive pressure in granular avalanches. Acta Geotechnica, 11(3), 549-557. https://doi.org/10.1007/s11440-016-0463-7
A computational procedure for instationary temperature-dependent snow creep
Bartelt, P., & Christen, M. (1999). A computational procedure for instationary temperature-dependent snow creep. In K. Hutter, Y. Wang, & H. Beer (Eds.), Leclure notes in physics: Vol. 533. Advances in cold-region thermal engineering and sciences. Technological, environmental, and climatological impact. Proceedings of the 6th international symposium held in Darmstadt, Germany, 22-25 August 1999 (pp. 367-386). https://doi.org/10.1007/BFb0104195
A nonequilibrium treatment of heat and mass transfer in alpine snowcovers
Bartelt, P., Buser, O., & Sokratov, S. A. (2004). A nonequilibrium treatment of heat and mass transfer in alpine snowcovers. Cold Regions Science and Technology, 39(2-3), 219-242. https://doi.org/10.1016/j.coldregions.2004.04.005
Dispersive pressure, boundary jerk and configurational changes in debris flows
Bartelt, P., McArdell, B., Graf, C., Christen, M., & Buser, O. (2016). Dispersive pressure, boundary jerk and configurational changes in debris flows. International Journal of Erosion Control Engineering, 9(1), 1-6. https://doi.org/10.13101/ijece.9.1
Dynamic magnification factors for snow avalanche impact (with pile-up) on walls and pylons
Bartelt, P., Buser, O., Christen, M., & Caviezel, A. (2019). Dynamic magnification factors for snow avalanche impact (with pile-up) on walls and pylons. In M. Papadrakakis & M. Fragiadakis (Eds.), Vol. 3. COMPDYN 2019. 7th international conference on computational methods in structural dynamics and earthquake engineering. Proceedings (pp. 4376-4385). Institute of Structural Analysis and Antiseismic Research, School of Civil Engineering, National Technical University of Athens (NTUA).
Thermomechanical modelling of rock avalanches with debris, ice and snow entrainment
Bartelt, P., Christen, M., Bühler, Y., & Buser, O. (2018). Thermomechanical modelling of rock avalanches with debris, ice and snow entrainment. In A. S. Cardoso, J. L. Borges, P. A. Costa, A. T. Gomes, J. C. Marques, & C. S. Vieira (Eds.), Numerical methods in geotechnical engineering IX (pp. 1047-1054). Taylor & Francis.
A physical SNOWPACK model for the Swiss avalanche warning Part I: numerical model
Bartelt, P., & Lehning, M. (2002). A physical SNOWPACK model for the Swiss avalanche warning Part I: numerical model. Cold Regions Science and Technology, 35(3), 123-145. https://doi.org/10.1016/S0165-232x(02)00074-5
Die Auswirkungen des Klimawandels auf alpine Massenbewegungen: das WSL Forschungsprogramm CCAMM
Bast, A., Phillips, M., Bründl, M., Stähli, M., Bartelt, P., Ortner, G., & Schweizer, J. (2020). Die Auswirkungen des Klimawandels auf alpine Massenbewegungen: das WSL Forschungsprogramm CCAMM. FAN Agenda, Fachleute Naturgefahren Schweiz (1), 15-17.
Lawinen und andere Schneebewegungen
Bebi, P., Bartelt, P., & Rixen, C. (2019). Lawinen und andere Schneebewegungen. In T. Wohlgemuth, A. Jentsch, & R. Seidl (Eds.), UTB: Vol. 5018. Störungsökologie (pp. 175-187). Haupt Verlag.
 

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