References:
[1] M. Dilley, Chen R. S., Deichmann U., Lerner-Lam A. L., Arnold M. Natural disaster hotspots: a global risk analysis: The World Bank; 2005.
[2] L. Zhang, Zhang S., Huang R. J. E. g. Multi-hazard scenarios and consequences in Beichuan, China: the first five years after the 2008 Wenchuan earthquake. 2014; Vol.180, pp. 4-20.
[3] Y. Depietri, Dahal K., McPhearson T. J. N. H., Sciences E. S. Multi-hazard risks in New York City. 2018; Vol.18(12), pp. 3363-81.
[4] M. Pelling, Blackburn S. Megacities and the coast: risk, resilience and transformation: Routledge; 2014.
[5] M. S. Kappes, Keiler M., von Elverfeldt K., Glade T. J. N. h. Challenges of analyzing multi-hazard risk: a review. 2012; Vol.64(2), pp. 1925-58.
[6] N. Komendantova, Mrzyglocki R., Mignan A., Khazai B., Wenzel F., Patt A., et al. Multi-hazard and multi-risk decision-support tools as a part of participatory risk governance: Feedback from civil protection stakeholders. 2014; Vol.8, pp. 50-67.
[7] J. C. Gill, Malamud B. D. J. R. o. G. Reviewing and visualizing the interactions of natural hazards. 2014; Vol.52(4), pp. 680-722.
[8] W. Marzocchi, Garcia-Aristizabal A., Gasparini P., Mastellone M. L., Di Ruocco A. J. N. h. Basic principles of multi-risk assessment: a case study in Italy. 2012; Vol.62(2), pp. 551-73.
[9] T. Lung, Lavalle C., Hiederer R., Dosio A., Bouwer L. M. A multi-hazard regional level impact assessment for Europe combining indicators of climatic and non-climatic change. Global Environmental Change. 2013; Vol.23(2), pp. 522-36.
[10] D. Araya-Muñoz, Metzger M. J., Stuart N., Wilson A. M. W., Carvajal D. J. S. o. t. T. E. A spatial fuzzy logic approach to urban multi-hazard impact assessment in Concepción, Chile. 2017; Vol.576, pp. 508-19.
[11] O. Rahmati, Yousefi S., Kalantari Z., Uuemaa E., Teimurian T., Keesstra S., et al. Multi-Hazard Exposure Mapping Using Machine Learning Techniques: A Case Study from Iran. 2019; Vol.11(16), pp. 1943.
[12] H. R. Pourghasemi, Gayen A., Panahi M., Rezaie F., Blaschke T. Multi-hazard probability assessment and mapping in Iran. Science of the total environment. 2019; Vol.692, pp. 556-71.
[13] H. D. Skilodimou, Bathrellos G. D., Chousianitis K., Youssef A. M., Pradhan B. J. E. E. S. Multi-hazard assessment modeling via multi-criteria analysis and GIS: a case study. 2019; Vol.78(2), pp. 47.
[14] G. J. N. H. Barrantes. Multi-hazard model for developing countries. 2018; Vol.92(2), pp. 1081-95.
[15] B. Liu, Siu Y. L., Mitchell G. J. N. H., Sciences E. S. Hazard interaction analysis for multi-hazard risk assessment: a systematic classification based on hazard-forming environment. 2016; Vol.16(2), pp. 629-42.
[16] V. Gallina, Torresan S., Critto A., Sperotto A., Glade T., Marcomini A. J. J. o. e. m. A review of multi-risk methodologies for natural hazards: Consequences and challenges for a climate change impact assessment. 2016; Vol.168, pp. 123-32.
[17] M. A. Islam, Mitra D., Dewan A., Akhter S. H. J. O., Management C. Coastal multi-hazard vulnerability assessment along the Ganges deltaic coast of Bangladesh–A geospatial approach. 2016; Vol.127, pp. 1-15.
[18] M. Peng, Zhang L. J. L. Breaching parameters of landslide dams. 2012; Vol.9(1), pp. 13-31.
[19] S. Girgin, Necci A., Krausmann E. J. I. J. o. D. R. R. Dealing with cascading multi-hazard risks in national risk assessment: The case of Natech accidents. 2019; Vol.35, pp. 101072.
[20] D. E. Hart, Giovinazzi S., Byun D.-S., Davis C., Ko S. Y., Gomez C., et al. Enhancing resilience by altering our approach to earthquake and flooding assessment: multi-hazards. 2018, pp.
[21] S. Davoudi, Brooks E., Mehmood A. J. P. P., Research. Evolutionary resilience and strategies for climate adaptation. 2013; Vol.28(3), pp. 307-22.
[22] S. Menoni, Galderisi A., Ceudech A., Delmonaco G., Margottini C., Spizzichino D. FP6 Armonia Project—Applied Multi-Risk Mapping of Natural Hazards for Impact Assessment. Deliverable 51, Harmonised Hazard, Vulnerability and Risk Assessment Methods Informing Mitigation Strategies Addressing Land-Use Planning and Management 2006.
[23] E. Pilone, Demichela M., Baldissone G. J. S. The Multi-Risk Assessment Approach as a Basis for the Territorial Resilience. 2019; Vol.11(9), pp. 2612.
[24] D. E. Hart, Hawke K. A. Multi-Hazard Flooding Interactions in the Ōpāwaho Heathcote Catchment, Christchurch, New Zealand. 2016, pp.
[25] D. Todd, Moody L., Cobby D., Hart D., Hawke K., Purton K., et al. Multi-Hazard Analysis: Gap Analysis Report. 2017, pp.
[26] C. Davis, Giovinazzi S., Hart D., editors. Liquefaction induced flooding in Christchurch, New Zealand. ISSMGE Technical Committee TC203 Proc 6th International Conference on Earthquake Geotechnical Engineering, Christchurch, NZ Nov; 2015.
[27] R. Mahendra, Mohanty P. C., T Kumar S., Shenoi S., Nayak S. R. J. I. J. o. R. S. Coastal multi-hazard vulnerability mapping: a case study along the Coast of Nellore District, East coast of India. 2010; Vol.42(3), pp. 67-76.
[28] B. Sahoo, Bhaskaran P. K. J. J. o. e. m. Multi-hazard risk assessment of coastal vulnerability from tropical cyclones–A GIS based approach for the Odisha coast. 2018; Vol.206, pp. 1166-78.
[29] G. Thomas, Schmid R., Cousins W., Heron D., Lukovic B., editors. Post-earthquake fire spread between buildings–Correlation with 1931 Napier earthquake. Proc New Zealand Society for Earthquake Engineering Annual Conference, Napier; 2006.
[30] D. Dowrick, Rhoades D., Babor J., Beetham R. J. B. o. t. N. Z. N. S. f. E. E. Damage ratios for houses and microzoning effects in Napier in the magnitude 7.8 Hawke’s Bay, New Zealand, earthquake of 1931. 1995; Vol.28(2), pp. 134-45.
[31] H. s. B. E. Management. 1960 tsunami: Hawke's Bay Emergency Management; Available from: https://www.hbemergency.govt.nz/hazards/tsunami/.
[32] Reporter. Residents evacuated as streets turn into rivers 2004 Available from: https://www.nzherald.co.nz/hawkes-bay-today/news/article.cfm?c_id=1503462&objectid=10915535.
[33] M. Sharpe. Hawke's Bay flooding cuts off village and overloads Napier's wastewater system 2018 Available from: https://www.stuff.co.nz/dominion-post/news/106848300/school-and-roads-closed-as-heavy-rain-batters-hawkes-bay.
[34] D. Paton, Johnston D., Bebbington M. S., Lai C.-D., Houghton B. F. J. A. J. o. E. M., The. Direct and vicarious experience of volcanic hazards: implications for risk perception and adjustment adoption. 2000; Vol.15(4), pp. 58.
[35] K. Ronan, Johnston D., Paton D., editors. Communities' understanding of earthquake risk in the Hawke's Bay and Manawatu-Wanganui regions, New Zealand. NZSEE 2001 Conference; 2001.
[36] D. McIvor, Paton D. J. D. P., Journal M. A. I. Preparing for natural hazards: normative and attitudinal influences. 2007; Vol.16(1), pp. 79-88.
[37] S. A. Fraser, Power W. L., Wang X., Wallace L. M., Mueller C., Johnston D. M. J. N. H. Tsunami inundation in Napier, New Zealand, due to local earthquake sources. 2014; Vol.70(1), pp. 415-45.
[38] N. Horspool, Cousins W. J., Power W. L. Review of tsunami risk facing New Zealand: a 2015 update: GNS Science; 2015.
[39] T. Taylor. Hawke Bay Coastal Strategy. Report. Hawke's Bay Regional Council 2016.
[40] M. R. Elkortbawi. Insights into the Liquefaction Hazards in Napier and Hastings Based on the Assessment of Data from the 1931 Hawke's Bay, New Zealand, Earthquake: Virginia Tech; 2017.