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References

Published online by Cambridge University Press:  04 January 2024

Brian Stone, Jr.
Affiliation:
Georgia Institute of Technology
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Radical Adaptation
Transforming Cities for a Climate Changed World
, pp. 138 - 150
Publisher: Cambridge University Press
Print publication year: 2024

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References

Primary Sources

Brazil, may be the owner of 20% of the world’s water supply but it is still very thirsty. The World Bank, August 5, 2016: www.worldbank.org/en/news/feature/2016/07/27/how-brazil-managing-water-resources-new-report-scd.Google Scholar
Davies, W. Brazil drought: Sao Paulo sleepwalking into water crisis. BBC News, November 7, 2014: www.bbc.com/news/world-latin-america-29947965.Google Scholar
Angelakis, A. Minoan aqueducts: A pioneering technology. 1st International Symposium on Water and Wastewater Technologies in Ancient Civilizations, Iraklio, Greece, 28–30 October 2006.Google Scholar
Romero, S. A willing explorer of São Paulo’s polluted rivers. The New York Times, December 14, 2012.Google Scholar
Morcroft, G. Drought watch: One of Brazil’s biggest cities has only 100 days of water supply left. International Business Times, July 29, 2014.Google Scholar
Timerman, J. No one’s quite sure how São Paulo will survive its drought. CityLab [Bloomberg], February 5, 2015.Google Scholar
Watts, J. Brazil’s worst drought in history prompts protests and blackouts. The Guardian, January 23, 2015.Google Scholar
Philips, D. São Paulo faces critical water shortage as the World Cup prepares to kick off. The Guardian, May 21, 2014.Google Scholar
Gerberg, J. A megacity without water: São Paulo’s drought. Time Magazine, October 13, 2015.Google Scholar
Zaitchik, A. Rainforest on fire. The Intercept, July 6, 2019.Google Scholar
Gibbs, H., Munger, J., L’Roe, J., & Barreto, P. Did ranchers and slaughterhouses respond to zero-deforestation agreements in the Brazilian Amazon? Conservation Letters 9, 32–42 (2016).Google Scholar
Mongabay. Mean net primary production by ecosystem: https://rainforests.mongabay.com/03net_primary_production.htm.Google Scholar
Alexander, P. et al. Human appropriation of land for food: The role of diet. Global Environmental Change 41, 8898 (2016).Google Scholar
Cattle ranching in the Amazon region. Global Forest Atlas, Yale School of Forestry and Environmental Studies: https://globalforestatlas.yale.edu/amazon/land-use/cattle-ranching.Google Scholar
Schmidinger, K. & Stehfast, E. Including CO2 implications of land occupation in LCAs: Method and example for livestock products. International Journal of Lifecycle Assessment 17, 962972 (2012).Google Scholar
Butler, R. Ecology of the Amazon rainforest. Mongabay: https://rainforests.mongabay.com/amazon/rainforest_ecology.html.Google Scholar
Nobre, P., Malagutti, M., Urbano, D., Almeida, R., & Giarolla, E. Amazon deforestation and climate change in a coupled model simulation. Journal of Climate 22, 56865697 (2009).Google Scholar
Whately, M. & Lerer, R. Brazil drought: Water rationing alone won’t save São Paulo. The Guardian. February 11, 2015.Google Scholar
Vigna, A. Where has São Paulo’s water gone? Equal Times, May 18, 2015.Google Scholar
Watts, J. Brazil drought crisis leads to rationing and tensions. The Guardian, September 5, 2014.Google Scholar
Watts, J. The Amazon effect: How deforestation is starving São Paulo of water. The Guardian, November 28, 2017.Google Scholar
Brazil’s southeastern states are experiencing the worst drought the country has seen in over 80 years. Telesur, February 19, 2015.Google Scholar
Grabow, S. & Heskin, A. Foundations for a radical concept of planning. Journal of the American Institute of Planners 39, 106114 (1973).Google Scholar
Beard, V. Learning radical planning: The power of collective action. Planning Theory 2, 1335 (2003).Google Scholar
Miraftab, F. Insurgent planning: Situating radical planning in the global south. Planning Theory 8, 3250 (2009).Google Scholar
Jacobs, F. Black feminism and radical planning: New directions for disaster planning research. Planning Theory 18, 439 (2019).Google Scholar
Williams, R. & Steil, J. The past we step into and how we repair it: A normative framework for reparative planning. Journal of the American Planning Association (2022): https://doi.org/10.1080/01944363.2022.2154247.Google Scholar

Secondary Sources

Dutta, A. Railway protection force estimates 80 deaths on Shramik trains. Hindustan Times, May 30, 2020.Google Scholar
Kumar, A. India wilts as temperature hits 50 degrees Celsius. Phys.org (2021): https://phys.org/news/2020-05-india-wilts-heatwave-temperature-degrees.html.Google Scholar
Masters, J. Death Valley, California, breaks the all-time world heat record for the second year in a row. Yale Climate Connections, July 12, 2021: https://yaleclimateconnections.org/2021/07/death-valley-california-breaks-the-all-time-world-heat-record-for-the-second-year-in-a-row/.Google Scholar
Samenow, J. India’s hellish heat wave, in hindsight. The Washington Post, June 10, 2015.Google Scholar
Lim, C. L. Heat sepsis precedes heat toxicity in the pathophysiology of heat stroke: A new paradigm on an ancient disease. Antioxidants 7, 810 (2018).Google Scholar
Engelhardt, E. Apoplexy, cerebrovascular disease, and stroke: Historical evolution of terms and definitions. National Library of Medicine 11, 449453 (2017).Google Scholar
Jarcho, S. A Roman experience with heat stroke in 24 BC. Bulletin of the New York Academy of Medicine 43, 767768 (1967).Google Scholar
Leithead, C. S. & Lind, A. R. Heat Stress and Heat Disorders (Cassell & Co., 1964).Google Scholar
Mufson, S. Facing unbearable heat, Qatar has begun to air-condition the outdoors. The Washington Post, October 16, 2019.Google Scholar
Sherwood, S. C. & Huber, M. An adaptability limit to climate change due to heat stress. Proceedings of the National Academy of Sciences of the United States of America 107, 95529555 (2010).Google Scholar
Raymond, C., Matthews, T., & Horton, R. M. The emergence of heat and humidity too severe for human tolerance. Science Advances 6 (2020): https://doi.org/10.1126/sciadv.aaw1838.Google Scholar
Milman, O. 2020 was hottest year on record by narrow margin, NASA says. The Guardian, January 14, 2021.Google Scholar
Florida Department of Health. 1998 wildland fire outbreak. Factsheet: https://flbrace.org/images/docs/wildland-fire-factsheet.pdf.Google Scholar
Csongos, F. 1998 in review: A year of natural disasters. RadioFreeEurope: RadioLiberty, December 9, 1998.Google Scholar
Hernandez, A. & McGinley, L. Harvard study estimates thousands died in Puerto Rico due to Hurricane Maria. The Washington Post, May 29, 2018.Google Scholar
NOAA (National Oceanic and Atmospheric Association). 2017 Atlantic Hurricane Season. National Hurricane Center and Central Pacific Hurricane Center (2017): www.nhc.noaa.gov/data/tcr/index.php?season=2017&basin=atl.Google Scholar
Ingraham, C. Houston is experiencing its third “500-year” flood in 3 years: How is that possible? The Washington Post, August 29, 2017.Google Scholar
Schär, C. Climate extremes: The worst heat waves to come. Nature Climate Change 6, 128129 (2016).Google Scholar
Dunne, J. P., Stouffer, R. J., & John, J. G. Reductions in labour capacity from heat stress under climate warming. Nature Climate Change 3, 563566 (2013).Google Scholar
Cook-Anderson, G. Drought, urbanization were ingredients for Atlanta’s perfect storm. NASA: www.nasa.gov/topics/earth/features/atlanta_tornado.html.Google Scholar
Murray, B. On this date in 2008: The SEC basketball tournament tornado miracle shot. AlabamaWX (blog), March 14, 2017: www.alabamawx.com/?p=128876.Google Scholar
Cimons, M. Humans have been messing with the climate for thousands of years. Popular Science, September 19, 2018.Google Scholar
Stone, B. The City and the Coming Climate: Climate Change in the Places We Live (Cambridge University Press, 2012).Google Scholar
Stone, B., Vargo, J., & Habeeb, D. Managing climate change in cities: Will climate action plans work? Landscape and Urban Planning 107, 263271 (2012).Google Scholar
Habeeb, D., Vargo, J., & Stone, B. Rising heat wave trends in large US cities. Natural Hazards 76, 16511665 (2015).Google Scholar
Vaidyanathan, A., Malilay, J., Schramm, P., & Saha, S. Heat-related deaths: United States, 2004–2018. CDC Morbidity and Mortality Weekly Report (MMWR) 69, 729734 (2020).Google Scholar
Stone, B., Lanza, K., Mallen, E., Vargo, J., & Russell, A. Urban heat management in Louisville, Kentucky: A framework for climate adaptation planning. Journal of Planning and Education and Research 43, 346358 (2019).Google Scholar
Simpson, J. R. Urban forest impacts on regional cooling and heating energy use: Sacramento County case study. Journal of Arboriculture 24, 201214 (1998).Google Scholar
Turner-Skoff, J. & Cavender, N. The benefits of trees for livable and sustainable communities. Plants, People, Planet 1, 323335 (2019).Google Scholar
Ryu, Y. H., Bou-Zeid, E., Wang, Z. H., & Smith, J. A. Realistic representation of trees in an urban canopy model. Boundary Layer Meteorology 159, 193220 (2016).Google Scholar
Middel, A., Chhetri, N., & Quay, R. Urban forestry and cool roofs: Assessment of heat mitigation strategies in Phoenix residential neighborhoods. Urban Forestry & Urban Greening 14, 178186 (2015).Google Scholar
Zölch, T., Maderspacher, J., Wamsler, C., & Pauleit, S. Using green infrastructure for urban climate-proofing: An evaluation of heat mitigation measures at the micro-scale. Urban Forestry & Urban Greening 20, 305316 (2016).Google Scholar
Nowak, D. J. & Greenfield, E. J. Declining urban and community tree cover in the United States. Urban Forestry & Urban Greening 32, 3255 (2018).Google Scholar
Ziter, C. D., Pedersen, E. J., Kucharik, C. J. & Turner, M. G. Scale-dependent interactions between tree canopy cover and impervious surfaces reduce daytime urban heat during summer. Proceedings of the National Academy of Sciences of the United States of America 116, 75757580 (2019).Google Scholar
O’Neil-Dunne, J. A Report on the City of Cambridge’s Existing and Possible Tree Canopy (University of Vermont Spatial Analysis Laboratory, 2012): www.cambridgema.gov/-/media/Files/CDD/Climate/treecanopystudy/UVM_Tree_Study_20120807.pdf.Google Scholar
O’Neil-Dunne, J. A Report on the City of New York’s Existing and Possible Tree Canopy (University of Vermont Spatial Analysis Laboratory, 2010): www.fs.usda.gov/nrs/utc/reports/UTC_NYC_Report_2010.pdf.Google Scholar
O’Neil-Dunne, J. A Report on Washington, D.C.’s Urban Tree Canopy (University of Vermont Spatial Analysis Laboratory, 2010): www.uvm.edu/~joneildu/Blog/Reports/UTC_Report_DC.pdf.Google Scholar
O’Neil-Dunne, J. A Report on the City of Philadelphia’s Existing and Possible Tree Canopy (University of Vermont Spatial Analysis Laboratory, 2011): www.phila.gov/media/20200210164446/Urban-Tree-Canopy-Report-03-18-11.pdf.Google Scholar
O’Neil-Dunne, J. P. M. A Report on the City of Baltimore’s Existing and Possible Urban Tree Canopy (University of Vermont Spatial Analysis Laboratory, 2009): http://gis.w3.uvm.edu/utc/Reports/TreeCanopy_Report_BACI_2007.pdf.Google Scholar
Ramsey, J. Tree canopy cover and potential in Portland, OR: A spatial analysis of the urban forest and capacity for growth. Master’s thesis, Portland State University (2019): https://doi.org/10.15760/etd.6988.Google Scholar
Song, X. P., Tan, P. Y., Edwards, P., & Richards, D. The economic benefits and costs of trees in urban forest stewardship: A systematic review. Urban Forestry & Urban Greening 29, 162170 (2018).Google Scholar
Kunsch, A. & Parks, R. Tree Planting Cost-Benefit Analysis: A Case Study for Urban Forest Equity in Los Angeles (TreePeople, 2021): www.treepeople.org/wp-content/uploads/2021/07/tree-planting-cost-benefit-analysis-a-case-study-for-urban-forest-equity-in-los-angeles.pdf.Google Scholar
Hotz, R. L. To offset climate change scientists tout city trees and ultra-white paint. Wall Street Journal, June 4, 2021.Google Scholar
Labrie, S. Measuring how effectively the Toronto District School Board Management Plans have increased playground shade over a thirteen-year period. Master’s thesis, University of Toronto (2017).Google Scholar
US Centers for Disease Control and Prevention. Shade Planning for America’s Schools (2008): www.cdc.gov/cancer/skin/pdf/shade_planning.pdf.Google Scholar
Olsen, H., Kennedy, E., & Vanos, J. Shade provision in public playgrounds for thermal safety and sun protection: A case study across 100 play spaces in the United States. Landscape and Urban Planning 189, 200211 (2019).Google Scholar
Colter, K. R., Middel, A. C., & Martin, C. A. Effects of natural and artificial shade on human thermal comfort in residential neighborhood parks of Phoenix, Arizona, USA. Urban Forestry & Urban Greening 44 (2019): https://doi.org/10.1016/j.ufug.2019.126429.Google Scholar
Johansson, E. & Emmanuel, R. The influence of urban design on outdoor thermal comfort in the hot, humid city of Colombo, Sri Lanka. International Journal of Biometeorology 51, 119133 (2006).Google Scholar
Watanabe, S. & Ishii, J. Effect of outdoor thermal environment on pedestrians’ behavior selecting a shaded area in a humid subtropical region. Building and Environment 95, 3241 (2016).Google Scholar
Martinelli, L., Lin, T. P., & Matzarakis, A. Assessment of the influence of daily shadings pattern on human thermal comfort and attendance in Rome during summer period. Building and Environment 92, 3038 (2015).Google Scholar
Shashua-Bar, L., Pearlmutter, D., & Erell, E. The influence of trees and grass on outdoor thermal comfort in a hot-arid environment. International Journal of Climatology 31, 14981506 (2011).Google Scholar
Alvey, A. A., Wiseman, P. E., & Kane, B. Efficacy of conventional tree stabilization systems and their effect on short-term tree development. Arboriculture & Urban Forestry 35, 157164 (2009).Google Scholar
Krayenhoff, E. S., Broadbent, A., Zhao, L., et al. Cooling hot cities: A systematic and critical review of the numerical modelling literature. Environmental Research Letters, 16 (2021): https://doi.org/10.1088/1748-9326/abdcf1.Google Scholar
Santamouris, M., Synnefa, A., & Karlessi, T. Using advanced cool materials in the urban built environment to mitigate heat islands and improve thermal comfort conditions. Solar Energy 85, 30853102 (2011).Google Scholar
Li, X., Peoples, J., Yao, P., & Ruan, X. Ultrawhite BaSO4 Paints and Films for Remarkable Daytime Subambient Radiative Cooling. ASC Applied Materials and Interfaces 13, 2173321739 (2021).Google Scholar
Kumar, R., Mishra, V., Buzan, J., et al. Dominant control of agriculture and irrigation on urban heat island in India. Scientific Reports 7 (2017): https://doi.org/10.1038/s41598-017-14213-2.Google Scholar
Lu, Y. & Kueppers, L. Increased heat waves with loss of irrigation in the United States. Environmental Research Letters 10 (2015): https://doi.org/10.1088/1748-9326/10/6/064010.Google Scholar
Gao, K. & Santamouris, M. The use of water irrigation to mitigate ambient overheating in the built environment: Recent progress. Building and Environment 164 (2019): https://doi.org/10.1016/j.buildenv.2019.106346.Google Scholar
Broadbent, A. M., Coutts, A. M., Tapper, N. J., & Demuzere, M. The cooling effect of irrigation on urban microclimate during heat wave conditions. Urban Climate 23, 309329 (2018).Google Scholar
Hendel, M., Gutierrez, P., Colombert, M., Diab, Y., & Royon, L. Measuring the effects of urban heat island mitigation techniques in the field: Application to the case of pavement-watering in Paris. Urban Climate 16, 4358 (2016).Google Scholar
Maillard, P., David, F., Dechesne, M., Bailly, J., & Lesueur, E. Characterization of the Urban Heat Island and evaluation of a road humidification solution in the district of La Part-Dieu, Lyon (France). Techniques Sciences Méthodes 6, 2335 (2014).Google Scholar
Santamouris, M., Ding, L., Fiorito, F., et al. Passive and active cooling for the outdoor built environment: Analysis and assessment of the cooling potential of mitigation technologies using performance data from 220 large scale projects. Solar Energy 154, 1433 (2017).Google Scholar
Frank, T. After a $14-billion upgrade, New Orleans’ levees are sinking. Scientific American, April 11, 2019.Google Scholar
Ganuchcau, J. New Orleans flood August 2017. Climate Signals, December 4, 2018: www.climatesignals.org/events/new-orleans-flood-august–2017.Google Scholar
Evans, B. 46 tons of Mardi Gras beads found in clogged catch basins. The Times-Picayune/The New Orleans Advocate, January 25, 2018.Google Scholar
Craig, T. It wasn’t even a hurricane but heavy rains flooded New Orleans as pumps faltered. The Washington Post, August 9, 2017.Google Scholar
List of capital cities by elevation. Wikipedia (2022): https://en.wikipedia.org/wiki/List_of_capital_cities_by_elevation.Google Scholar
Dahl, K. A., Fitzpatrick, M. F., & Spanger-Siegfried, E. Sea level rise drives increased tidal flooding frequency at tide gauges along the U.S. East and Gulf Coasts: Projections for 2030 and 2045. PLOS One 12 (2017): https://doi.org/10.1371/journal.pone.0170949.Google Scholar
National Park Service. The Potowmack Canal: www.nps.gov/grfa/learn/historyculture/canal.htm.Google Scholar
Prillaman, M. Are we in the Anthropocene? Geologists could define new epoch for Earth. Nature 623, 1415 (2023).Google Scholar
Intergovernmental Panel on Climate Change (IPCC). The Physical Science Basis. In Masson-Delmotte, V., Zhai, P., Pirani, A et al. (eds.), Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change (Cambridge University Press, 2021).Google Scholar
Slater, T., Lawrence, I., Otosaka, I., et al. Review article: Earth’s ice imbalance. Cryosphere 15, 233246 (2021).Google Scholar
Chen, X., Zhang, X., Church, J., et al. The increasing rate of global mean sea-level rise during 1993–2014. Nature Climate Change 7, 492495 (2017).Google Scholar
Shultz, K., Nguyen, T., & Pillar, H. An improved and observationally-constrained melt rate parameterization for vertical ice fronts of marine terminating glaciers. Geophysical Research Letters 49, e2022GL100654 (2022).Google Scholar
Bott, L. M., Schon, T., Illigner, J., et al. Land subsidence in Jakarta and Semarang Bay: The relationship between physical processes, risk perception, and household adaptation. Ocean & Coastal Management 211 (2021): https://doi.org/10.1016/j.ocecoaman.2021.105775.Google Scholar
Dejong, B., Bierman, P., Newell, W., et al. Pleistocene relative sea levels in the Chesapeake Bay region and their implications for the next century. Geological Society of America Today 25, 410 (2015).Google Scholar
Tabari, M. Climate change impact on flood and extreme precipitation increases with water availability. Scientific Reports 10, 13768 (2020).Google Scholar
Papalexiou, S. M. & Montanari, A. Global and regional increase of precipitation extremes under global warming. Water Resources Research 55, 49014914 (2019).Google Scholar
Janssen, E., Wuebbles, D. J., Kunkel, K. E., Olsen, S. C., & Goodman, A. Observational‐ and model‐based trends and projections of extreme precipitation over the contiguous United States. Earth’s Future 2, 99113 (2014).Google Scholar
Fischer, E. M. & Knutti, R. Observed heavy precipitation increase confirms theory and early models. Nature Climate Change 6, 986991 (2016).Google Scholar
Myhre, G. et al. Frequency of extreme precipitation increases extensively with event rareness under global warming. Scientific Reports 9, 211 (2019).Google Scholar
Express News Service. Gulp it down: Chennai rainfall among highest in last 200 years! The New Indian Express, November 28, 2021.Google Scholar
Luu, L. N., Scussolini, P., Kew, S., et al. Attribution of typhoon-induced torrential precipitation in Central Vietnam, October 2020. Climatic Change 169, 122 (2021).Google Scholar
Hollingsworth, J. More than 100 dead as Vietnam reels from “worst floods in decades.” CNN, October 21, 2020.Google Scholar
English, E. C., Li, M., Zarins, R., & Feltham, T. H. H. The economic argument for amphibious retrofit construction. Paper presented at the 8th International Conference on Building Resilience – ICBR, Lisbon, November 14–16, 2018.Google Scholar
Busscher, T., van den Brink, M., & Verweij, S. Strategies for integrating water management and spatial planning: Organising for spatial quality in the Dutch “Room for the River” program. Journal of Flood Risk Management 12, 112 (2019).Google Scholar
ClimateWire. How the Dutch make “Room for the River” by redesigning cities. Scientific American, January 20, 2012.Google Scholar
Oosthoek, K. J. Dutch river defenses in historical perspective. Environmental History Resources (2006): www.eh-resources.org/dutch-river-defences-in-historical-perspective/#_ednref6.Google Scholar
Rubin, S. In Amsterdam, a community of floating homes shows the world how to live alongside nature. The Washington Post, December 17, 2021.Google Scholar
Hartman, K. J., Ap, L., Stieve, D. R., & Associates, E. Floodproofing New York: The City’s Response to Superstorm Sandy (International Institute of Building Enclosure Consultants, 2018): https://iibec.org/wp-content/uploads/2018-cts-hartman-stieve.pdf.Google Scholar
Parkinson, R. W. Speculation on the role of sea-level rise in the tragic collapse of the Surfside condominium (Miami Beach, Florida U.S.A.) was a bellwether moment for coastal zone management practitioners. Ocean & Coastal Management 215, 105968 (2021).Google Scholar
Clark, J. Premium Elevation, LLC. Connection 19, 1820 (2021).Google Scholar
Hanks, D. & Ortiz, R. Will Dade enact a 60-day notice for rent increases over 5%? Miami Herald, February 23, 2022.Google Scholar
Tan, R., Kornfield, M., & Brice-Saddler, M. In Miami’s gentrifying neighborhoods, Surfside condo collapse deepens fears of displacement. The Washington Post, July 17, 2021.Google Scholar
Hillier, A. E. Redlining and the Home Owners’ Loan Corporation. Journal of Urban History 29, 394420 (2003).Google Scholar
Wilson, B. Urban heat management and the legacy of redlining. Journal of the American Planning Association 86, 443457 (2020).Google Scholar
Lukes, D. & Cleveland, C. The lingering legacy of redlining on school funding, Diversity, and Performance. EdWorkingPaper No. 21-363, 21363 (2021).Google Scholar
Capps, K. & Cannon, C. Redlined, now flooding. Bloomberg, March 15, 2021.Google Scholar
Hoffman, J. S., Shandas, V., & Pendleton, N. The effects of historical housing policies on resident exposure to intra-urban heat: A study of 108 US urban areas. Climate 8, 112 (2020).Google Scholar
Winship, S., Pulliam, C., Shiro, A., Reeves, R., & Deambrosi, S. Long Shadows: The Black–White Gap in Multigeneration Poverty (The Brookings Institution, 2021): www.brookings.edu/research/long-shadows-the-black-white-gap-in-multigenerational-poverty/.Google Scholar
Lavizzo-Mourey, R. & Williams, D. Being black is bad for your health. US News & World Report, April 14, 2016.Google Scholar
Garrison, J. D. Seeing the park for the trees: New York’s “Million Trees” campaign vs. the deep roots of environmental inequality. Environment and Planning B: Urban Analytics and City Science 46, 914930 (2019).Google Scholar
Murray-Cooper, A. Justice in Urban Climate Plans: How and Where Cities Are Integrating Equity and Climate. Boston University Initiative on Cities (2021). www.bu.edu/ioc/2021/11/01/justice-in-urban-climate-plans-how-and-where-cities-are-integrating-equity-and-climate/.Google Scholar
Radtke Russell, P. Threats of “Day Zero” water scarcity multiply. Engineering News-Record, July 20, 2020.Google Scholar
Parvatam, S. & Priyadarshini, S. On Day Zero, India prepares for a water emergency. Nature India, June 30, 2019.Google Scholar
Oppili, P. 80% of Chennai was wetland in 1980s, now 15%. The Times of India, September 5, 2016.Google Scholar
C40. The 2015 C40 Cities Award Winner’s Circle. C40 Cities (blog), June 2, 2016: www.c40.org/blog_posts/the-2015-c40-cities-award-winners-circle.Google Scholar
Prabahakaran, S. & Sule, T. Cape Town: Towards a sustainable water future. Urban Water Atlas, May 9, 2020: www.urbanwateratlas.com/2020/05/09/cape-town-towards-a-sustainable-water-future/.Google Scholar
Alexander, C. Cape Town’s “Day Zero” water crisis: One year later. Bloomberg, April 12, 2019.Google Scholar
Zilber, A. NEWBrew beer in Singapore is made from recycled sewage water. New York Post, June 30, 2022.Google Scholar
VOANews, Singapore turns sewage into clean, drinkable water, meeting 40% of demand. VOANews, August 10, 2021.Google Scholar
BBC World News. The 11 cities most likely to run out of drinking water – like Cape Town. BBC News, February 11, 2018.Google Scholar
Chiang, F., Mazdiyasni, O., & AghaKouchak, A. Evidence of anthropogenic impacts on global drought frequency, duration, and intensity. Nature Communications 12 (2021): https://doi.org/10.1038/s41467-021-22314-w.Google Scholar
Xu, L., Chen, N., & Zhang, X. Global drought trends under 1.5 and 2°C warming. International Journal of Climatology 39, 23752385 (2019).Google Scholar
Carrington, D. Climate limit of 1.5°C close to being broken, scientists warn. The Guardian, May 9, 2022.Google Scholar
Sognnaes, I., Gambhir, A., Van de ven, D., et al. A multi-model analysis of long-term emissions and warming implications of current mitigation efforts. Nature Climate Change 11, 10551062 (2021).Google Scholar
United Nations Environment Program. Emissions Gap Report 2021 (2021): www.unep.org/resources/emissions-gap-report-2021.Google Scholar
Nowak, D. J. & Greenfield, E. J. Tree and impervious cover change in U.S. cities. Urban Forestry & Urban Greening 11, 2130 (2012).Google Scholar
US Environmental Protection Agency (EPA). Water efficiency for water suppliers: Water efficiency strategies (2023): www.epa.gov/sustainable-water-infrastructure/water-efficiency-water-suppliers.Google Scholar
Los Angeles County Waterworks Districts. Drought frequently asked questions: https://dpw.lacounty.gov/wwd/web/Conservation/droughtinfoFAQ.aspx.Google Scholar
Brulliard, K. The Colorado River is in crisis, and it’s getting worse every day. The Washington Post, May 14, 2022.Google Scholar
Slivka, K. A Mayan water system with lessons for today. The New York Times, July 16, 2012.Google Scholar
Teston, A., Geraldi, M. S., Colasio, B. M. & Ghisi, E. Rainwater harvesting in buildings in Brazil: A literature review. Water 10, 471 (2018).Google Scholar
Campisano, A., Butler, D., Ward, S., et al. Urban rainwater harvesting systems: Research, implementation and future perspectives. Water Research 115, 195209 (2017).Google Scholar
Pushkarna, V. Rainwater harvesting: Delhi’s focus moves from rooftops to public parks and other open spaces. Citizen Matters, July 12, 2022.Google Scholar
Han, M. Progress of multipurpose and proactive rainwater management in Korea. Environmental Engineering Research 18, 6569 (2013).Google Scholar
US Environmental Protection Agency (EPA). Stormwater Best Management Practices: Permeable Pavements. Report no. EPA-832-F-21-031W (EPA, 2021).Google Scholar
Amol, P., Priyanka, K., & Onkar, S. Green Roof Market Size, Share & Trends Analysis Report by Type, by Application, by Region, and Segment Forecasts, 2020–2027. Report no. GVR-3-68038-183-2 (Grand View Research, 2020): www.grandviewresearch.com/industry-analysis/green-roof-market.Google Scholar
United States Congress. Infrastructure Investment and Jobs Act. 117–58 (2021).Google Scholar
Seliktar, O. Turning water into fire: The Jordan River as the hidden factor in the Six Day War. Middle East Review of International Affairs, 9: 5771 (2005).Google Scholar
Novo, C. Israel leads the way in wastewater reuse. Smart Water Magazine, July 29, 2020.Google Scholar
Rabinovitch, A., Barrington, L., & Al-Khalidi, S. Israel, Jordan to partner in water-for-energy deal. Reuters, November 8, 2021.Google Scholar
Ding, J. Los Angeles could soon put recycled water directly in your tap. It’s not “toilet to tap.” Los Angeles Times, July 22, 2022.Google Scholar
Alawadhi, A. & Tartakovsky, D. M. Bayesian update and method of distributions: Application to leak detection in transmission mains. Water Resources Research 56, 110 (2020).Google Scholar
Blount, S. Home water use in the United States. National Environmental Education Foundation: www.neefusa.org/weather-and-climate/weather/home-water-use-united-states.Google Scholar
European Environment Agency. Water use in Europe: Quantity and quality face big challenges (2018): www.eea.europa.eu/signals/signals-2018-content-list/articles/water-use-in-europe–2014.Google Scholar
Luby, I. H., Polasky, S., & Swackhamer, D. L. US urban water prices: Cheaper when drier. Water Resources Research 54, 61266132 (2018).Google Scholar
Parks, R., Mclaren, M., Toumi, P. R., & Rivett, P. U. Experiences and lessons in managing water from Cape Town. London Imperial College, Grantham Institute Briefing Paper No. 29 (2019): www.imperial.ac.uk/media/imperial-college/grantham-institute/public/publications/briefing-papers/Experiences-and-lessons-in-managing-water.pdf.Google Scholar
Shapiro, A. Cape Town averts “Day Zero” by limiting water use. National Public Radio, June 28, 2018.Google Scholar
Urban Sustainability Exchange, City of Cape Town’s Water Map: https://use.metropolis.org/case-studies/city-of-cape-towns-water-map.Google Scholar
Yoon, J. Ian becomes a hurricane again as it takes aim at South Carolina. The New York Times, September 29, 2022.Google Scholar
Stebbins, S. Cape Coral is one of the fastest growing cities in America. 24/7 Wall St (2021): https://247wallst.com/city/cape-coral-is-one-of-the-fastest-growing-cities-in-america/.Google Scholar
Victor, D. Hurricane Andrew: How The Times reported the destruction of 1992. The New York Times, September 6, 2017.Google Scholar
National Hurricane Center. Tropical cyclone naming history and retired names: www.nhc.noaa.gov/aboutnames_history.shtml.Google Scholar
Tavernise, S. Did Hurricane Ian bust Florida’s housing boom? The New York Times, October 18, 2022.Google Scholar
Allen, G. Hurricane Katrina: 10 years of recovery and reflection ghosts of Katrina still haunt New Orleans’ shattered Lower Ninth Ward. National Public Radio, August 3, 2015.Google Scholar
Flavelle, C. Hurricane Ian’s toll is severe. Lack of insurance will make it worse. The New York Times, September 9, 2022.Google Scholar
FEMA. Moving out of harm’s way proves advantageous and gives rise to widely used park (2021): www.fema.gov/case-study/moving-out-harms-way-proves-advantageous-and-gives-rise-widely-used-park.Google Scholar
PEW. Repeatedly flooded properties cost billions. Infographic (2016): www.pewtrusts.org/-/media/assets/2016/10/repeatedly_flooded_properties_cost_billions.pdf.Google Scholar
Painter, W. L. The Disaster Relief Fund: Overview and Issues (Congressional Research Services, 2022): https://sgp.fas.org/crs/homesec/R45484.pdf.Google Scholar
US Government Accountability Office. Flood mitigation: Actions needed to improve use of FEMA property acquisitions. September (2022): www.gao.gov/products/gao-22-106037.Google Scholar
Hauer, M. E., Evans, J. M., & Mishra, D. R. Millions projected to be at risk from sea-level rise in the continental United States. Nature Climate Change 6, 691695 (2016).Google Scholar
Pinter, N. True stories of managed retreat from rising waters. Issues in Science and Technology 37, 6473 (2021).Google Scholar
US National Park Service. Native American Heritage of the Niobrara (2020): https://www.nps.gov/niob/native-american-heritage-of-the-niobrara.htm.Google Scholar
Davis, M. Cahokia: North America’s massive, ancient city. Big Think (2023): https://bigthink.com/the-past/cahokia/.Google Scholar
Seppa, N. Metropolitan life on the Mississippi. The Washington Post, March 12, 1997.Google Scholar
Newitz, A. Four Lost Cities: A Secret History of the Urban Age (W. W. Norton & Company, 2021).Google Scholar
Cottar, S., Doberstein, B., Henstra, D., & Wandel, J. Evaluating property buyouts and disaster recovery assistance (rebuild) options in Canada: A comparative analysis of Constance Bay, Ontario and Pointe Gatineau, Quebec. Natural Hazards 109, 201220 (2021).Google Scholar
Donovan, L. Buyouts on the ballot: 10 years after Sandy, New York considers new funding for voluntary relocation. City Limits, October 24, 2022.Google Scholar
New York Proposal 1, Environmental Bond Measure. Ballotpedia (2022): https://ballotpedia.org/New_York_Proposal_1,_Environmental_Bond_Measure_(2022).Google Scholar
Alexander, K. Reclaiming paradise. San Francisco Chronicle, May 3, 2019.Google Scholar
Siegler, K. In fire scorched California, town aims to buy the highest at-risk properties. National Public Radio, August 23, 2021.Google Scholar
Agyeman, J., Devine-Wright, P., & Prange, J. Close to the edge, down by the river? Joining up managed retreat and place attachment in a climate changed world. Environment and Planning A: Economy and Space 41, 509513 (2009).Google Scholar
Galway, L. P., Beery, T., Jones-Casey, K., & Tasala, K. Mapping the solastalgia literature: A scoping review study. International Journal of Environmental Research and Public Health 16 (2019): https://doi.org/10.3390/ijerph16152662.Google Scholar
US Department of the Interior. Biden–Harris administration makes $135 million commitment to support relocation of tribal communities affected by climate change. (2022): www.doi.gov/pressreleases/biden-harris-administration-makes-135-million-commitment-support-relocation-tribal.Google Scholar
Georgetown Climate Center. Managing the Retreat from Rising Seas (Georgetown Climate Center, 2020): www.georgetownclimate.org/files/MRT/GCC_20_FULL-3web.pdf.Google Scholar
Kulp, S. A. & Strauss, B. H. New elevation data triple estimates of global vulnerability to sea-level rise and coastal flooding. Nature Communications 10 (2019): https://doi.org/10.1038/s41467-019-12808-z.Google Scholar
Flavelle, C. Trump administration presses cities to evict homeowners from flood zones. The New York Times, March 11, 2020.Google Scholar
Zambrano, L. Cape Coral residents weather Hurricane Ian: ‘It’s been a catastrophic event for the city’. Fort Myers News-Press, September 29, 2022.Google Scholar
US Environmental Protection Agency (EPA). Fast facts on transportation greenhouse gas emissions (2022): www.epa.gov/greenvehicles/fast-facts-transportation-greenhouse-gas-emissions.Google Scholar
Plumer, B. Cars take up way too much space in cities. New technology could change that. Vox (2016): www.vox.com/a/new-economy-future/cars-cities-technologies.Google Scholar
Pruetz, R. Ecocity Snapshots: Nijmegen Netherlands – Room for the River. Ecocities Emerging (2017): https://ecocitiesemerging.org/nijmegen-netherlands-room-for-the-river/.Google Scholar
Faulkner, T. Before and after: Innovative design fights flooding in Atlanta. Trust for Public Land (2023): www.tpl.org/stories/cook-park-atlanta-green-infrastructure-flooding.Google Scholar
Atlanta Regional Commission (ARC). Neighborhood Statistical Area L01 Fact Sheet (2023): http://documents.atlantaregional.com/NN/Profiles/AtlantaProfiles/L01.pdf.Google Scholar
Stevens, A. Study: 4 Atlanta neighborhoods among nation’s most dangerous. Atlanta Journal Constitution, October 5, 2010.Google Scholar
Wang, Y., Shen, J. K., Xiang, W., & Wang, J. Q. Identifying characteristics of resilient urban communities through a case study method. Journal of Urban Management 7, 141151 (2018).Google Scholar
Saporta, M. Westside Future Fund offers lessons on building communities from the ground up. Saporta Report, January 23, 2023.Google Scholar
Green, J. Five years after Mercedes-Benz Stadium broke ground, is Atlanta’s Westside revival working? Curbed Atlanta, January 31, 2019.Google Scholar
Park Pride. Proctor Creek North Avenue Watershed Basin: A Green Infrastructure Vision (Park Pride, 2010). https://parkpride.org/wp-content/uploads/2016/09/2010_pna_overview-1.pdf.Google Scholar
AgLanta. Fresh Food Access Report City of Atlanta 2020 (Department of City Planning and AgLanta, 2020): www.aglanta.org/2020-fresh-food-access-report.Google Scholar

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  • References
  • Brian Stone, Jr., Georgia Institute of Technology
  • Book: Radical Adaptation
  • Online publication: 04 January 2024
  • Chapter DOI: https://doi.org/10.1017/9781009211192.007
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  • References
  • Brian Stone, Jr., Georgia Institute of Technology
  • Book: Radical Adaptation
  • Online publication: 04 January 2024
  • Chapter DOI: https://doi.org/10.1017/9781009211192.007
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  • References
  • Brian Stone, Jr., Georgia Institute of Technology
  • Book: Radical Adaptation
  • Online publication: 04 January 2024
  • Chapter DOI: https://doi.org/10.1017/9781009211192.007
Available formats
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