Abstract
Volcanic disasters are characterized by complexity, a wide range of intensities, long duration, and rarity. Since volcanic eruptions are accompanied by the ejection of a large number of magma products, resilience to volcanic hazards is basically ensured by evacuation planning. Resilience with respect to volcanic ashfall can be increased by a quick response to its impacts. The traffic network is most severely affected by volcanic ashfall and dispersion. The removal of volcanic ash from the traffic network, particularly roads, is the first step in logistics recovery. Judgment of timing to start recovery is important in order to enhance resilience through rapid recovery and is ensured by monitoring of volcanic activity.
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References
Aramaki S (1956/1957) The 1783 activity of Asama Volcano. Parts 1 and 2. Jpn J Geol Geogr 27:189–229, 28:11–33
Badan Geologi (2011) Kelud. In Data Dasar Gunung Api Indonesia, pp 372–399
Casadevall TJ (1992) Volcanic hazards and aviation safety-lessons of the past decade. FAA Aviation Safety J 2(3):9–17
Hayakawa Y (1993) A proposal of eruption magnitude scale. Bull Volcanol Soc Jpn 38:223–226
Cotel AJ (1999) A trigger mechanism for the Lake Nyos disaster. J Volcanol Geotherm Res 88:343–347
Iguchi M, Nakamichi H, Tameguri T, Yamamoto K, Mori T, Ohminato T, Saito E (2017) Contribution of monitoring data to decision making for evacuation from the 2014 and 2015 eruptions of Kuchinoerabujima Volcano. J Nat Disast Sci 38:31–47
Kagoshima city (2018) Hazard map of Sakurajima volcano
Kagoshima prefecture (2018) Kagoshima prefecture regional disaster prevention plan: Volcano disaster measures edition
Lipman PW, Mullineaux DR (eds) (1981) The 1980 eruptions of Mount St. Helens. Washington. US Geol Surv Prof Pap 1250, pp 1–844
Nakada S, Shimizu H, Ohta K (1999) Overview of the 1990–1995 eruption at Unzen Volcano. J Volcano Geotherm Res 1–22
Newhall CG, Self S (1982) The volcanic explosivity index (VEI): an estimate of explosive magnitude for historical volcanism. J Geophys Res 87(C2):1231–1238
Osumi Office of River and National Highway, Kyushu Regional Development Bureau, Ministry of Land, Infrastructure and Transport (2007) Wide-area hazard map of Sakurajima volcano
Sakamoto M, Kuri M, Iguchi M, Maki N, Ichiko T, Sekiya N, Kobayashi H (2016) Disaster Governance in disaster management planning—analysis of the evacuation planning process for Kuchinoerabujima Volcano eruption. J Nat Disast Sci 37:105–117
Self S, Rampino MR (1981) The 1883 eruption of Krakatau. Nature 294:699–704
Voight B, Calvache ML, Hall ML, Monsalve ML (2013) Nevado del Ruiz Volcano, Colombia 1985. In: Bobrowsky PT (eds) Encyclopedia of natural hazards. Encyclopedia of Earth Sciences series. Springer, Dordrecht
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Iguchi, M. (2020). Resilience to Volcano- and Landslide-Related Hazards. In: Yokomatsu, M., Hochrainer-Stigler, S. (eds) Disaster Risk Reduction and Resilience. Disaster and Risk Research: GADRI Book Series. Springer, Singapore. https://doi.org/10.1007/978-981-15-4320-3_3
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DOI: https://doi.org/10.1007/978-981-15-4320-3_3
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