| Innovative high-speed camera array for unprecedented insights inito powder snow avalanches
Calic, I., Coletti, F., Roth, B., & Sovilla, B. (2024). Innovative high-speed camera array for unprecedented insights inito powder snow avalanches. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 288-292). Norwegian Geotechnical Institute. |
| New insights into snow avalanche dynamics and entrainment mechanisms from depht-resolved particle-based simulations
Gaume, J., Ligneau, C., Huitorel, C., Li, X., Kyburz, M., Sovilla, B., … Vicari, H. (2024). New insights into snow avalanche dynamics and entrainment mechanisms from depht-resolved particle-based simulations. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 306-313). Norwegian Geotechnical Institute. |
| Are our avalanche impact pressure equations fit for a warming climate? - Insights from 3D avalanche modeling
Kohler, M. J., Gaume, J., & Sovilla, B. (2024). Are our avalanche impact pressure equations fit for a warming climate? - Insights from 3D avalanche modeling. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 299-305). Norwegian Geotechnical Institute. |
| New inferences on the importance of slope-normal snow avalanche velocity components from depth-resolved avalanche simulations
Kyburz, M. L., Margreth, S., Berner, F., Sovilla, B., & Gaume, J. (2024). New inferences on the importance of slope-normal snow avalanche velocity components from depth-resolved avalanche simulations. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 387-392). Norwegian Geotechnical Institute. |
| Potential and challenges of depth-resolved three-dimensional MPM simulations: a case study of the 2019 "salezer" snow avalanche in Davos
Kyburz, M. L., Sovilla, B., Bühler, Y., & Gaume, J. (2024). Potential and challenges of depth-resolved three-dimensional MPM simulations: a case study of the 2019 "salezer" snow avalanche in Davos. Annals of Glaciology, 65, e19 (14 pp.). https://doi.org/10.1017/aog.2024.14 |
| Transient wave activity in snow avalanches is controlled by entrainment and topography
Li, X., Sovilla, B., Gray, J. M. N. T., & Gaume, J. (2024). Transient wave activity in snow avalanches is controlled by entrainment and topography. Communications Earth & Environment, 5(1), 77 (11 pp.). https://doi.org/10.1038/s43247-023-01157-x |
| Modelling erosion, entrainment and deposition in cohesive granular flows: application to dense snow avalanches
Ligneau, C., Sovilla, B., & Gaume, J. (2024). Modelling erosion, entrainment and deposition in cohesive granular flows: application to dense snow avalanches. Cold Regions Science and Technology, 219, 104103 (14 pp.). https://doi.org/10.1016/j.coldregions.2023.104103 |
| Integrating automated avalanche detections for validating and explaining avalanche forecasting models
Pérez-Guillén, C., Simeon, A., Techel, F., Volpi, M., Sovilla, B., & van Herwijnen, A. (2024). Integrating automated avalanche detections for validating and explaining avalanche forecasting models. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 52-57). Norwegian Geotechnical Institute. |
| Assessing the drivers controlling the development of airborne layers in powder snow avalanches through infrasound analysis
Sovilla, B., Pérez-Guillén, C., Köhler, A., Marchetti, E., & Suriñach, E. (2024). Assessing the drivers controlling the development of airborne layers in powder snow avalanches through infrasound analysis. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 293-298). Norwegian Geotechnical Institute. |
| Riders and avalanches floating on powder snow: new insights into air pore pressure mechanisms from hydro-mechanical numerical simulations
Vicari, H., Huitorel, C., Tran, Q. A., Sovilla, B., & Gaume, J. (2024). Riders and avalanches floating on powder snow: new insights into air pore pressure mechanisms from hydro-mechanical numerical simulations. In K. Gisnås, P. Gauer, H. Dahle, M. Eckerstorfer, A. Mannberg, & K. Müller (Eds.), Proceedings of the international Snow Science Workshop 2024 (pp. 321-326). Norwegian Geotechnical Institute. |
| Recent advances in modeling snow and avalanches with the material point method and practical implications
Gaume, J., Blatny, L., Bobillier, G., Guillet, L., Kohler, M. J., Kyburz, M., … Védrine, L. (2023). Recent advances in modeling snow and avalanches with the material point method and practical implications. In Proceedings of the international Snow Science Workshop (ISSW 2023) (pp. 408-414). Norwegian Geotechnical Institute. |
| Phenomenology of avalanche recordings from distributed acoustic sensing
Paitz, P., Lindner, N., Edme, P., Huguenin, P., Hohl, M., Sovilla, B., … Fichtner, A. (2023). Phenomenology of avalanche recordings from distributed acoustic sensing. Journal of Geophysical Research F: Earth Surface, 128(5), e2022JF007011 (18 pp.). https://doi.org/10.1029/2022JF007011 |
| Physics-based estimates of drag coefficients for the impact pressure calculation of dense snow avalanches
Kyburz, M. L., Sovilla, B., Gaume, J., & Ancey, C. (2022). Physics-based estimates of drag coefficients for the impact pressure calculation of dense snow avalanches. Engineering Structures, 254, 113478 (17 pp.). https://doi.org/10.1016/j.engstruct.2021.113478 |
| The concept of the mobilized domain: how it can explain and predict the forces exerted by a cohesive granular avalanche on an obstacle
Kyburz, M. L., Sovilla, B., Gaume, J., & Ancey, C. (2022). The concept of the mobilized domain: how it can explain and predict the forces exerted by a cohesive granular avalanche on an obstacle. Granular Matter, 24(2), 45 (17 pp.). https://doi.org/10.1007/s10035-021-01196-1 |
| Different erosion and entrainment mechanisms in snow avalanches
Li, X., Sovilla, B., Ligneau, C., Jiang, C., & Gaume, J. (2022). Different erosion and entrainment mechanisms in snow avalanches. Mechanics Research Communications, 124, 103914 (8 pp.). https://doi.org/10.1016/j.mechrescom.2022.103914 |
| Numerical investigation of the effect of cohesion and ground friction on snow avalanches flow regimes
Ligneau, C., Sovilla, B., & Gaume, J. (2022). Numerical investigation of the effect of cohesion and ground friction on snow avalanches flow regimes. PLoS One, 17(2), e0264033 (24 pp.). https://doi.org/10.1371/journal.pone.0264033 |
| Destructiveness of pyroclastic surges controlled by turbulent fluctuations
Brosch, E., Lube, G., Cerminara, M., Esposti-Ongaro, T., Breard, E. C. P., Dufek, J., … Fullard, L. (2021). Destructiveness of pyroclastic surges controlled by turbulent fluctuations. Nature Communications, 12(1), 7306 (12 pp.). https://doi.org/10.1038/s41467-021-27517-9 |
| Powder snow impact of tall vibrating structures
Caviezel, A., Margreth, S., Ivanova, K., Sovilla, B., & Bartelt, P. (2021). Powder snow impact of tall vibrating structures. In M. Papadrakakis & M. Fragiadakis (Eds.), Compdyn 2021 proceedings (p. 19112 (13 pp.). https://doi.org/10.7712/120121.8868.19112 |
| Three-dimensional and real-scale modeling of flow regimes in dense snow avalanches
Li, X., Sovilla, B., Jiang, C., & Gaume, J. (2021). Three-dimensional and real-scale modeling of flow regimes in dense snow avalanches. Landslides, 18, 3393-3406. https://doi.org/10.1007/s10346-021-01692-8 |
| Decoupling the role of inertia, friction, and cohesion in dense granular avalanche pressure build-up on obstacles
Kyburz, M. L., Sovilla, B., Gaume, J., & Ancey, C. (2020). Decoupling the role of inertia, friction, and cohesion in dense granular avalanche pressure build-up on obstacles. Journal of Geophysical Research F: Earth Surface, 125(2), e2019JF005192 (18 pp.). https://doi.org/10.1029/2019JF005192 |