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Taranaki; New Zealand (2010)
Official, Figure in a journal article
An example of a volcanic hazard map for Mount Taranaki
Figure 2 in: Becker, J.S., Saunders, W.S.A., Robertson, C.M., Leonard, G.S., & Johnston, D.M. (2010). A synthesis of challenges and opportunities for reducing volcanic risk through land use planning in New Zealand. The Australasian Journal of Disaster and Trauma Studies, 2010-1. (Simplified from: Taranaki Regional Council 2004)
Official, Figure in a journal article
An example of a volcanic hazard map for Mount Taranaki
Figure 2 in: Becker, J.S., Saunders, W.S.A., Robertson, C.M., Leonard, G.S., & Johnston, D.M. (2010). A synthesis of challenges and opportunities for reducing volcanic risk through land use planning in New Zealand. The Australasian Journal of Disaster and Trauma Studies, 2010-1. (Simplified from: Taranaki Regional Council 2004)
Taranaki; New Zealand (2022)
Figure in a journal article
Count of ballistic particle impacts per 10,000 ballistic particles with a diameter of 256 mm
Figure 8 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Figure in a journal article
Count of ballistic particle impacts per 10,000 ballistic particles with a diameter of 256 mm
Figure 8 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Taranaki; New Zealand (2022)
Figure in a journal article
Exceedance probability for volcanic mass flows reaching or travelling further than Taranaki crossing track following a VEI≤2 eruption
Figure 7 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Figure in a journal article
Exceedance probability for volcanic mass flows reaching or travelling further than Taranaki crossing track following a VEI≤2 eruption
Figure 7 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Taranaki; New Zealand (2004)
Official, Unknown format
Ground hugging effects of a volcanic eruption
Taranaki Regional Council. (2004). Civil Defence Emergency Management, Group Plan for Taranaki. Stratford.
Official, Unknown format
Ground hugging effects of a volcanic eruption
Taranaki Regional Council. (2004). Civil Defence Emergency Management, Group Plan for Taranaki. Stratford.
Taranaki; New Zealand (2010)
Figure in a journal article
Hazard zone created from Titan2D computer simulations based on the 1:300 year BAF event from a dome collapse and 3D representation of the created Hazard zone
Figure 5 in: Procter, J. N., Cronin, S. J., Platz, T., Patra, A., Dalbey, K., Sheridan, M., & Neall, V. (2010). Mapping block-and-ash flow hazards based on Titan 2D simulations: a case study from Mt. Taranaki, NZ. Natural Hazards, 53, 483-501.
Figure in a journal article
Hazard zone created from Titan2D computer simulations based on the 1:300 year BAF event from a dome collapse and 3D representation of the created Hazard zone
Figure 5 in: Procter, J. N., Cronin, S. J., Platz, T., Patra, A., Dalbey, K., Sheridan, M., & Neall, V. (2010). Mapping block-and-ash flow hazards based on Titan 2D simulations: a case study from Mt. Taranaki, NZ. Natural Hazards, 53, 483-501.
Taranaki; New Zealand (1993)
Official, Figure in hazard assessment
Landslide, Lahar and Associated Flood Hazard Zones Map
Map 3, Page 20 in: Neall, V.E. & Alloway, B.V. (1993). Volcanic hazards at Egmont volcano. Volcanic Hazards Working Group of the Scientific Advisory Committee, Ministry of Civil Defence. Volcanic Hazards Information Series, Number One, 2nd ed. 31 p.
Official, Figure in hazard assessment
Landslide, Lahar and Associated Flood Hazard Zones Map
Map 3, Page 20 in: Neall, V.E. & Alloway, B.V. (1993). Volcanic hazards at Egmont volcano. Volcanic Hazards Working Group of the Scientific Advisory Committee, Ministry of Civil Defence. Volcanic Hazards Information Series, Number One, 2nd ed. 31 p.
Taranaki; New Zealand (1993)
Official, Figure in hazard assessment
Lava Flow and Lava Dome Hazard Zone Map
Map 1, Page 15 in: Neall, V.E. & Alloway, B.V. (1993). Volcanic hazards at Egmont volcano. Volcanic Hazards Working Group of the Scientific Advisory Committee, Ministry of Civil Defence. Volcanic Hazards Information Series, Number One, 2nd ed. 31 p.
Official, Figure in hazard assessment
Lava Flow and Lava Dome Hazard Zone Map
Map 1, Page 15 in: Neall, V.E. & Alloway, B.V. (1993). Volcanic hazards at Egmont volcano. Volcanic Hazards Working Group of the Scientific Advisory Committee, Ministry of Civil Defence. Volcanic Hazards Information Series, Number One, 2nd ed. 31 p.
New Zealand (regional); New Zealand (2006)
Figure in a journal article
Mean simulated tephra thickness within the Auckland Region
Figure 6 in: Magill, C. R., Hurst, A. W., Hunter, L. J., & Blong, R. J. (2006). Probabilistic tephra fall simulation for the Auckland Region, New Zealand. Journal of volcanology and geothermal research, 153(3-4), 370-386. https://doi.org/10.1016/j.jvolgeores.2005.12.002
Figure in a journal article
Mean simulated tephra thickness within the Auckland Region
Figure 6 in: Magill, C. R., Hurst, A. W., Hunter, L. J., & Blong, R. J. (2006). Probabilistic tephra fall simulation for the Auckland Region, New Zealand. Journal of volcanology and geothermal research, 153(3-4), 370-386. https://doi.org/10.1016/j.jvolgeores.2005.12.002
Taranaki; New Zealand (2022)
Figure in a journal article
Minimum factor of safety for Mt. Taranaki edifice
Figure 9 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Figure in a journal article
Minimum factor of safety for Mt. Taranaki edifice
Figure 9 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Taranaki; New Zealand (2022)
Figure in a journal article
Potential failure volumes for FOS <3.0 at Mt. Taranaki
Figure 10 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531
Figure in a journal article
Potential failure volumes for FOS <3.0 at Mt. Taranaki
Figure 10 in: Mead, S., Procter, J., Bebbington, M., & Rodriguez-Gomez, C. (2022). Probabilistic Volcanic Hazard Assessment for National Park Infrastructure Proximal to Taranaki Volcano (New Zealand). Frontiers in Earth Science, 435. https://doi.org/10.3389/feart.2022.832531