Adaptive Pathways for Resilient Infrastructure in an Evolving Disasterscape

IF 2.7 Q2 ENGINEERING, CIVIL

Sustainable and Resilient Infrastructure Pub Date : 2022-11-24 DOI:10.1080/23789689.2022.2148951

Amit Prothi, Mona Chhabra Anand, Ratnesh Kumar

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引用次数: 1

Abstract

The human pursuit of greater well-being through better and faster growth paths for economic and social development is as old as the anthropocene itself. Infrastructure creation is at the core of this pursuit. However, infrastructure systems suffer due to disasters triggered by natural hazards, manmade events and impacts of climate change, compromising much of the development dividend of investments in these systems. To ensure that infrastructure can withstand predictable shocks, continue to provide essential services during crises and bounce back stronger to their full performance swiftly, there is a need to develop climate and disaster-resilient infrastructure. Infrastructure resilience is a dynamic concept with innate complex attributes, such as assurance of service delivery, interdependence between systems and long life of assets in dynamic environmental contexts. Complexities of infrastructure resilience are further compounded by uncertainty engendered by climate change, socio-political instabilities and economic growth. Given the scale of investment required, infrastructure development is typically undertaken with a 10 to 50-year horizon. However, rapid changes in environmental contexts and technological evolution, along with user expectations for faster and better services limit the extents of ‘long term’ thinking. A case in point is the current push for net zero energy transition that has triggered a shift towards cleaner energy sources such as hydrogen. However, hydrogen generation requires renewable energy sources such as wind to deliver on its environmental objectives fully and in coastal areas and island contexts, off-shore wind energy infrastructure is highly vulnerable to various hazards such as cyclones and tsunamis, rendering the entire net zero energy value chain at risk. Likewise, the unprecedented floods of 2021 in Ahr valley (Germany), New York (USA), Black Sea region (Turkey) and Kolhapur (India) are testimony that the past is no longer a good guide for the future. Analysis of past trends provide limited information to define the problem or the solutions we propose in the form of infrastructure systems. Such situations prompt the question: How do we develop resilient infrastructure for a not-so-distant, dynamic, and highly uncertain future?

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在不断变化的灾害环境中实现弹性基础设施的适应性路径

人类通过更好更快的经济和社会发展增长途径追求更大的福祉，这与人类世本身一样古老。基础设施建设是这一追求的核心。然而，基础设施系统受到自然灾害、人为事件和气候变化影响引发的灾害的影响，损害了这些系统投资的大部分发展红利。为了确保基础设施能够承受可预测的冲击，在危机期间继续提供基本服务，并迅速恢复到更强劲的全面表现，有必要发展气候和抗灾基础设施。基础设施弹性是一个动态概念，具有内在的复杂属性，如服务提供的保证、系统之间的相互依存性以及动态环境中资产的长寿命。气候变化、社会政治不稳定和经济增长带来的不确定性进一步加剧了基础设施复原力的复杂性。考虑到所需的投资规模，基础设施开发通常需要10到50年的时间。然而，环境环境和技术发展的快速变化，以及用户对更快、更好服务的期望，限制了“长期”思维的范围。一个恰当的例子是目前推动净零能源转型，这引发了向氢等清洁能源的转变。然而，制氢需要风能等可再生能源来充分实现其环境目标，在沿海地区和岛屿环境中，离岸风能基础设施极易受到飓风和海啸等各种灾害的影响，使整个净零能源价值链面临风险。同样，2021年在Ahr valley（德国）、纽约（美国）、黑海地区（土耳其）和Kolhapur（印度）发生的前所未有的洪水证明，过去不再是未来的好指南。对过去趋势的分析提供了有限的信息来定义问题或我们以基础设施系统的形式提出的解决方案。这种情况引发了一个问题：我们如何为不那么遥远、充满活力和高度不确定的未来发展有弹性的基础设施？

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Sustainable and Resilient Infrastructure ENGINEERING, CIVIL-

CiteScore

7.60

自引率

10.20%

发文量

期刊介绍： Sustainable and Resilient Infrastructure is an interdisciplinary journal that focuses on the sustainable development of resilient communities. Sustainability is defined in relation to the ability of infrastructure to address the needs of the present without sacrificing the ability of future generations to meet their needs. Resilience is considered in relation to both natural hazards (like earthquakes, tsunami, hurricanes, cyclones, tornado, flooding and drought) and anthropogenic hazards (like human errors and malevolent attacks.) Resilience is taken to depend both on the performance of the built and modified natural environment and on the contextual characteristics of social, economic and political institutions. Sustainability and resilience are considered both for physical and non-physical infrastructure.