Abstract
The unexpectedly poor performances of complex mitigation systems in recent natural disasters demonstrate the need to reexamine mitigation system functionality, especially those combining multiple mitigation strategies. A systematic classification of mitigation strategies is presented as a basis for understanding how different types of strategy within an overall mitigation system can interfere destructively, to reduce the effectiveness of the system as a whole. We divide mitigation strategies into three classes according to the timing of the actions that they prescribe. Permanent mitigation strategies prescribe actions such as construction of tsunami barriers or land-use restrictions: they are frequently both costly and “brittle” in that the actions work up to a design limit of hazard intensity or magnitude and then fail. Responsive mitigation strategies prescribe actions after a hazard source event has occurred, such as evacuations, that rely on capacities to detect and quantify hazard events and to transmit warnings fast enough to enable at risk populations to decide and act effectively. Anticipatory mitigation strategies prescribe use of the interpretation of precursors to hazard source events as a basis for precautionary actions, but challenges arise from uncertainties in hazard behaviour. The NE Japan tsunami mitigation system and its performance in the 2011 Tohoku disaster provide examples of interactions between mitigation strategies. We propose that the classification presented here would enable consideration of how the addition of a new strategy to a mitigation system would affect the performance of existing strategies within that system, and furthermore aid the design of integrated mitigation systems.
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Acknowledgments
We would like to thank Victoria Sword-Daniels for comments on an earlier version of the manuscript, and Chris Kilburn, Steve Edwards for comments and encouragement regarding the concepts presented here. We would also like to thank two anonymous reviewers for their comments that motivated substantial changes to the manuscript. This work was not directly funded.
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Day, S., Fearnley, C. A classification of mitigation strategies for natural hazards: implications for the understanding of interactions between mitigation strategies. Nat Hazards 79, 1219–1238 (2015). https://doi.org/10.1007/s11069-015-1899-z
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DOI: https://doi.org/10.1007/s11069-015-1899-z