Current and Future Exposure of Infrastructure in the United States to Natural Hazards

Willis, Henry H.; Narayanan, Anu; Fischbach, Jordan R.; Molina-Pérez, Edmundo; Stelzner, Chuck; Loa, Kathleen; Kendrick, Lauren

doi:10.7249/rr1453

Cited by 12 publications

(14 citation statements)

References 2 publications

(6 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Many regions around the world have also experienced a rising number of costly disastrous events (Fischer & Knutti 2015, Idier et al 2017, IPCC 2012, Wallemacq & House 2018. The observed increase in the impacts of extreme events directly reflects increases in exposure to natural hazards (i.e., due to population growth and development), vulnerability of existing infrastructure systems (IPCC 2012, Neumann et al 2015, Willis et al 2016, and climate change and variability (IPCC 2012).…”

Section: Introductionmentioning

confidence: 99%

“…In turn, heavier precipitation events exacerbate the risk of flooding, debris flows, and rainfall-triggered landslides (Gariano & Guzzetti 2016). Increased flood risk in coastal regions is further amplified by sea level rise (Buchanan et al 2017, Jongman et al 2012, Vitousek et al 2017, threatening the integrity of coastal infrastructure systems and assets (Hallegatte et al 2013, Neumann et al 2015, Willis et al 2016. Population and development projections show a continued trend of rapidly expanding urbanization, particularly in coastal zones, which increases both vulnerability and exposure to extremes (Hauer et al 2016, Neumann et al 2015.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Climate Extremes and Compound Hazards in a Warming World

AghaKouchak

Chiang

Huning

et al. 2020

Annu. Rev. Earth Planet. Sci.

475

213

View full text Add to dashboard Cite

Climate extremes threaten human health, economic stability, and the well-being of natural and built environments (e.g., 2003 European heat wave). As the world continues to warm, climate hazards are expected to increase in frequency and intensity. The impacts of extreme events will also be more severe due to the increased exposure (growing population and development) and vulnerability (aging infrastructure) of human settlements. Climate models attribute part of the projected increases in the intensity and frequency of natural disasters to anthropogenic emissions and changes in land use and land cover. Here, we review the impacts, historical and projected changes,and theoretical research gaps of key extreme events (heat waves, droughts, wildfires, precipitation, and flooding). We also highlight the need to improve our understanding of the dependence between individual and interrelated climate extremes because anthropogenic-induced warming increases the risk of not only individual climate extremes but also compound (co-occurring) and cascading hazards. ▪ Climate hazards are expected to increase in frequency and intensity in a warming world. ▪ Anthropogenic-induced warming increases the risk of compound and cascading hazards. ▪ We need to improve our understanding of causes and drivers of compound and cascading hazards.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Climate Extremes and Compound Hazards in a Warming World

AghaKouchak

Chiang

Huning

et al. 2020

Annu. Rev. Earth Planet. Sci.

475

213

View full text Add to dashboard Cite

show abstract

“…Given that unusual, very large events reside in the right tail of the frequency‐size distribution, we defined hazard hotspots as pixels where event probability or magnitude exceeded the 90th percentile of all unique values in CONUS. Hotpots therefore correspond to the most hazardous subregions of hazard zones used in exposure assessments (e.g., Willis et al., 2016 , and references therein). Historically, the most devastating natural disasters, such as the San Francisco earthquake (California; April 1906; ∼3,000 fatalities; ∼11 billion inflation‐adjusted 2019 USD loss), Galveston hurricane (Texas and Oklahoma; September 1900; 6,000–12,000 fatalities; ∼1 billion inflation‐adjusted 2019 USD), and the tri‐state tornado (Illianois, Indiana, and Missouri; March 1925; 629 fatalities; ∼2.3 billion inflation‐adjusted 2019 USD) occurred in these hazard hotspots.…”

Section: Resultsmentioning

confidence: 99%

“…One of the most significant barriers in national scale risk assessments is inadequate characterization of development patterns (Willis et al., 2016 ). The use of fine‐scale data on the built environment provides advances in risk assessment including (a) more accurate identification of exposed structures, (b) detailed information on the characteristics of the places where people live, work and recreate, and (c) assessment of the land development patterns leading to changes in exposure (e.g., expansion and densification).…”

Section: Discussionmentioning

confidence: 99%

Risky Development: Increasing Exposure to Natural Hazards in the United States

et al. 2021

View full text Add to dashboard Cite

show abstract

“…The American Society of Civil Engineers' report card in 2017, however, estimated that the average age of dams in the United States is about 59 years with an overall score of "D," which suggests many dams are in a poor to fair state (American Society of Civil Engineers, 2017). Consequently, the original dam design does not reliably account for changes in potential exposure of these important infrastructure assets to flood hazards in the future (Willis et al, 2016). Therefore, their construction did not incorporate the current and possible future changes in the hydrological condition.…”

Section: Introductionmentioning

confidence: 99%

Climate‐Induced Changes in the Risk of Hydrological Failure of Major Dams in California

Mallakpour

AghaKouchak

Sadegh

2019

Geophysical Research Letters

View full text Add to dashboard Cite

Existing major reservoirs in California, with average age above 50 years, were built in the previous century with limited data records and flood hazard assessment. Changes in climate and land use are anticipated to alter statistical properties of inflow to these infrastructure systems and potentially increase their hydrological failure probability. Because of large socioeconomic repercussions of infrastructure incidents, revisiting dam failure risks associated with possible shifts in the streamflow regime is fundamental for societal resilience. Here we compute historical and projected flood return periods as a proxy for potential changes in the risk of hydrological failure of dams in a warming climate. Our results show that hydrological failure probability is likely to increase for most dams in California by 2100. Noticeably, the New Don Pedro, Shasta, Lewiston, and Trinity Dams are associated with highest potential changes in flood hazard.

show abstract

Current and Future Exposure of Infrastructure in the United States to Natural Hazards

Cited by 12 publications

References 2 publications

Climate Extremes and Compound Hazards in a Warming World

Climate Extremes and Compound Hazards in a Warming World

Risky Development: Increasing Exposure to Natural Hazards in the United States

Climate‐Induced Changes in the Risk of Hydrological Failure of Major Dams in California

Contact Info

Product

Resources

About