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Figure in a journal article
Ash fallout simulations with an 8-km column height and volume of 0.05 km³
Figure 8 in: Bartolini, S., Bolós, X., Martí, J., Pedra, E. R., & Planagumà, L. (2015). Hazard assessment at the quaternary La Garrotxa volcanic field (NE Iberia). Natural Hazards, 78(2), 1349-1367. https://doi.org/10.1007/s11069-015-1774-y
Figure in a journal article
Ash load probability maps for Martinique using the 41-year wind database and considering the 16 eruptive scenarios
Figure 8 in: Michaud-Dubuy, A., Carazzo, G., & Kaminski, E. (2021). Volcanic hazard assessment for tephra fallout in Martinique. Journal of Applied Volcanology, 10(1), 1-20. https://doi.org/10.1186/s13617-021-00106-7.
Figure in a journal article
Ash loading probability maps for the maximum expected eruption scenario
Figure 5 in: Michaud-Dubuy, A., Carazzo, G., & Kaminski, E. (2021). Volcanic hazard assessment for tephra fallout in Martinique. Journal of Applied Volcanology, 10(1), 1-20. https://doi.org/10.1186/s13617-021-00106-7.
Official, Figure in a journal article
Ash thickness (in metres) from our model for 1 Ma of eruptions from Taupo and Okataina centres
Figure 9 in: Hurst, T. & Smith, W. (2010). Volcanic ashfall in New Zealand–probabilistic hazard modelling for multiple sources. New Zealand Journal of Geology and Geophysics, 53(1), 1-14. https://doi.org/10.1080/00288301003631129
Figure in a journal article
Ash-fall hazard map
Figure 10 in: Marrero, J. M., García, A., Berrocoso, M., Llinares, Á., Rodríguez-Losada, A., & Ortiz, R. (2019). Strategies for the development of volcanic hazard maps in monogenetic volcanic fields: the example of La Palma (Canary Islands). Journal of Applied Volcanology, 8(1), 6. https://doi.org/10.1186/s13617-019-0085-5
Figure in a journal article
Ashfall models for A and B scenarios
Figure 8 in: Alpízar, Y., Fernández, M., Ramírez, C., & Arroyo, D. (2019). Hazard Map of Rincón de la Vieja Volcano, Costa Rica: Qualitative Integration of Computer Simulations and Geological Data. Anuario do Instituto de Geociencias, 42(3). http://dx.doi.org/10.11137/2019_3_474_488
Figure in a journal article
Ashfall scenarios from a violent Strombolian eruption performed with VORIS 2.0.1.
Figure 6 in: Becerril, L., Bartolini, S., Sobradelo, R., Martí, J., Morales, J. M., & Galindo, I. (2014). Long-term volcanic hazard assessment on El Hierro (Canary Islands). Natural Hazards and Earth System Sciences, 14(7), 1853-1870. https://doi.org/10.5194/nhess-14-1853-2014, 2014
Figure in a journal article
Assessment and zonation of hazards from future lahars of phreatic and collapse-type at Soufrière in Guadeloupe (according to Westercamp, 1981b)
Figure 10.5 in: Westercamp, D. (1983). Appraisal and zonation of volcanic hazards in the French Lesser Antilles: preliminary results. In: Tazieff, H. & Sabroux, J.-C. (Eds.) Forecasting Volcanic Events, Elsevier, Amsterdam, p. 111-130.
Figure in a journal article
Atmospheric dispersion of tephra for a threshold of 2 mg m−3 for all FL for the eruption scenarios of Hekla ERS 1947-type (a, b, c), Katla LLERS (d, e, f) and Askja OES 1875-type (g, h, i)
Figure 13 in: Biass, S., Scaini, C., Bonadonna, C., Folch, A., Smith, K., & Höskuldsson, A. (2014). A multi-scale risk assessment for tephra fallout and airborne concentration from multiple Icelandic volcanoes–Part 1: Hazard assessment. Natural hazards and earth system sciences, 14(8), 2265-2287. https://doi.org/10.5194/nhess-14-2265-2014
Figure in a journal article
BA hazard maps displaying the yearly mean probability of areas being impacted by BA
Figure 8 in: Sandri, L., Thouret, J. C., Constantinescu, R., Biass, S., & Tonini, R. (2014). Long-term multi-hazard assessment for El Misti volcano (Peru). Bulletin of volcanology, 76(2), 771. https://doi.org/10.1007/s00445-013-0771-9