Leopold, A. A Sand County Almanac. Oxford University Press, 1949.Google Scholar

Bandy, L. Causes and cures VIII: Environmental violence. Aggression and Violent Behavior 30 (2016):105–109.Google Scholar

Barca, S. Telling the right story: Environmental violence and liberation narratives. Environment and History 20.4 (2014):535–546.Google Scholar

de la Cueva Salcedo, H. Environmental violence and its consequences. Latin American Perspectives 42.5 (2015):19–26.CrossRefGoogle Scholar

Horowitz, LS. Environmental violence and crises of legitimacy in New Caledonia. Political Geography 28.4 (2009):248–258.Google Scholar

Peluso, NL, Watts, M. Violent Environments. Cornell University Press, 2001.Google Scholar

Radonic, L. Environmental violence, water rights, and (un)due process in northwestern Mexico. Latin American Perspectives 42.5 (2015):27–47.Google Scholar

Zimmerer, J. Climate change, environmental violence and genocide. International Journal of Human Rights 18.3 (2014):265–280.Google Scholar

Laland, KN, Odling-Smee, FJ, Feldman, MW. Evolutionary consequences of niche construction and their implications for ecology. Proceedings of the National Academy of Sciences of the United States of America 96.18 (1999):10242–10247.Google Scholar

Laland, KN, Uller, T, Feldman, MW, et al. The extended evolutionary synthesis: Its structure, assumptions and predictions. Proceedings of the Royal Society B: Biological Sciences 282.1813 (2015):20151019.Google ScholarPubMed

Odling-Smee, FJ, Odling-Smee, H, Laland, KN, et al. Niche Construction: The Neglected Process in Evolution. Princeton University Press, 2003.Google Scholar

Ellis, EC, Richerson, PJ, Mesoudi, A, et al. Evolving the human niche. Proceedings of the National Academy of Sciences of the United States of America 113.31 (2016):E4436.Google Scholar

Fuentes, A. Human evolution, niche complexity, and the emergence of a distinctively human imagination. Time and Mind 7.3 (2014):241–257.Google Scholar

Fuentes, A, Baynes-Rock, M. Anthropogenic landscapes, human action and the process of co-construction with other species: Making anthromes in the Anthropocene. Land 6.1 (2017):15.Google Scholar

Boivin, N, Zeder, MA, Fuller, R, et al. Ecological consequences of human niche construction: Examining long-term anthropogenic shaping of global species distributions. Proceedings of the National Academy of Sciences of the United States of America 113.23 (2016):6388–6396.Google Scholar

OED. Violence. In Oxford English Dictionary: The Definitive Record of the English Language. 2nd ed. Oxford University Press, 1989.Google Scholar

Hickel, J. Quantifying national responsibility for climate breakdown: An equality-based attribution approach for carbon dioxide emissions in excess of the planetary boundary. The Lancet Planetary Health 4.9 (2020):e399–e404.Google Scholar

Matthews, HD. Quantifying historical carbon and climate debts among nations. Nature Climate Change 6.1 (2016):60–64.Google Scholar

UNEP (United Nations Environment Programme). The emissions gap report 2020. United Nations Environment Programme, 2020 [cited December 17, 2020]. p. 128. Available from: www.unep.org/emissions-gap-report-2020Google Scholar

O’Neill, DW, Fanning, AL, Lamb, WF, et al. A good life for all within planetary boundaries. Nature Sustainability 1.2 (2018):88–95.Google Scholar

Fanning, AL, O’Neill, DW. The wellbeing–consumption paradox: Happiness, health, income, and carbon emissions in growing versus non-growing economies. Journal of Cleaner Production 212 (2019):810–821.Google Scholar

Fuller, R, Sandilya, K, Hanrahan, D. Pollution and Health Metrics. Global Alliance on Health and Pollution, 2019 [cited February 18, 2020] p. 56. Available from: https://gahp.net/wp-content/uploads/2019/12/PollutionandHealthMetrics-final-12_18_2019.pdfGoogle Scholar

GAHP (Global Alliance on Health and Pollution). Air Pollution Interventions: Seeking the Intersection between Climate and Health. Global Alliance on Health and Pollution, 2020 [cited May 12, 2021] p. 85. Available from: https://gahp.net/wp-content/uploads/2020/06/AirPollutionReport2-compressed-1.pdfGoogle Scholar

IPCC (Intergovernmental Panel on Climate Change). Summary for policymakers. Climate Change 2021: The Physical Science Basis Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, 2021 [cited August 20, 2021] p. 42. Available from: https://www.ipcc.ch/report/ar6/wg1/Google Scholar

Landrigan, PJ, Fuller, R, Haines, A, et al. Pollution prevention and climate change mitigation: Measuring the health benefits of comprehensive interventions. The Lancet Planetary Health 2.12 (2018):e515–e516.Google Scholar

Marcantonio, R, Field, S, Regan, PM. Toxic trajectories under future climate conditions. PLOS ONE 14.12 (2019):e0226958.Google Scholar

Marcantonio, R, Field, S, Regan, PM. Toxicity travels in a changing climate. Environmental Science & Policy 114 (2020):560–569.Google Scholar

Marcantonio, R, Javeline, D, Field, S, et al. Global distribution and coincidence of pollution, climate impacts, and health risk in the Anthropocene. PLOS ONE 16.7 (2021):e0254060Google Scholar

Raymond, C, Horton, RM, Zscheischler, J, et al. Understanding and managing connected extreme events. Nature Climate Change 10.7 (2020):611–621.Google Scholar

Romanello, M, McGushin, A, Napoli, CD, et al. The 2021 report of The Lancet countdown on health and climate change: Code red for a healthy future. The Lancet 0.0 (2021):44.Google Scholar

Watts, N, Amann, M, Arnell, N, et al. The 2020 report of The Lancet countdown on health and climate change: Responding to converging crises. The Lancet 397.10269 (2021):129–170.Google Scholar

Steffen, W, Crutzen, PJ, McNeill, JR. The Anthropocene: Are humans now overwhelming the great forces of nature. AMBIO: A Journal of the Human Environment 36.8 (2007):614–621.Google Scholar

Vollset, SE, Goren, E, Yuan, C-W, et al. Fertility, mortality, migration, and population scenarios for 195 countries and territories from 2017 to 2100: A forecasting analysis for the Global Burden of Disease Study. The Lancet 396.10258 (2020):1285–1306.Google Scholar

Worldometer. World population clock, 2019 [cited February 18, 2019]. Available from: www.worldometers.info/world-population/Google Scholar

Motesharrei, S, Rivas, J, Kalnay, E, et al. Modeling sustainability: Population, inequality, consumption, and bidirectional coupling of the Earth and Human Systems. National Science Review 3.4 (2016):470–494.Google ScholarPubMed

UNPD (United Nations Development Programme). World Population Prospects 2017 – Volume I: Comprehensive Tables. United Nations Department of Economic and Social Affairs, 2019 [cited October 12, 2021]. Available from: www.un-ilibrary.org/content/books/9789210001014Google Scholar

Liddle, B. What are the carbon emissions elasticities for income and population? Bridging STIRPAT and EKC via robust heterogeneous panel estimates. Global Environmental Change 31 (2015):62–73.Google Scholar

O’Neill, DW. Beyond green growth. Nature Sustainability 3.4 (2020):260–261.Google Scholar

Hickel, J. Is it possible to achieve a good life for all within planetary boundaries? Third World Quarterly 40.1 (2019):18–35.Google Scholar

Oswald, Y, Owen, A, Steinberger, JK. Large inequality in international and intranational energy footprints between income groups and across consumption categories. Nature Energy 5.3 (2020):231–239.Google Scholar

Krausmann, F, Erb, K-H, Gingrich, S, et al. Global human appropriation of net primary production doubled in the 20th century. PNAS 110.25 (2013):10324–10329.Google Scholar

McNeill, JR. Something New Under the Sun. Norton, 2001.Google Scholar

UNDP (United Nations Development Programme). Human Development Index (HDI): Human development reports. United Nations Development Programme, 2019 [cited December 30, 2019] p. 2. Available from: http://hdr.undp.org/en/content/human-development-index-hdiGoogle Scholar

Imhoff, ML, Bounoua, L, Ricketts, T, et al. Global patterns in human consumption of net primary production. Nature 429.6994 (2004): 870–873.Google Scholar

Hickel, J, Kallis, G. Is green growth possible? New Political Economy 25.4 (2020):469–486.CrossRefGoogle Scholar

Wiedmann, TO, Schandl, H, Lenzen, M, et al. The material footprint of nations. PNAS 112.20 (2015):6271–6276.Google Scholar

Lees, S, Bates, D. The ecology of cumulative change. In Moran, EF, ed. The Ecosystems Approach in Anthropology. University of Michigan Press, 1990, pp. 133–159.Google Scholar

Moran, EF. The Ecosystem Approach in Anthropology: From Concept to Practice. University of Michigan Press, 1990.Google Scholar

Lansing, JS. Complex adaptive systems. Annual Review of Anthropology 32.1 (2003):183–204.Google Scholar

Ellis, EC. Ecology in an anthropogenic biosphere. Ecological Monographs 85.3 (2015):287–331.Google Scholar

Rockström, J, Steffen, W, Noone, K, et al. Planetary boundaries: Exploring the safe operating space for humanity. Ecology and Society 14.2 (2009) [cited August 13, 2020]. Available from: www.jstor.org/stable/26268316Google Scholar

Folke, C. Resilience: The emergence of a perspective for social–ecological systems analyses. Global Environmental Change 16.3 (2006):253–267.Google Scholar

Steffen, W, Richardson, K, Rockström, J, et al. Planetary boundaries: Guiding human development on a changing planet. Science 347.6223 (2015):1259855.Google Scholar

Steffen, W, Rockström, J, Richardson, K, et al. Trajectories of the Earth System in the Anthropocene. PNAS (2018):201810141.Google Scholar

Potts, R. Evolution and environmental change in early human prehistory. Annual Review of Anthropology 41.1 (2012):151–167.Google Scholar

Scheffers, BR, De Meester, L, Bridge, TCL, et al. The broad footprint of climate change from genes to biomes to people. Science 354.6313 (2016):719–731.Google Scholar

Ellis, EC. Why is human niche construction transforming planet Earth? Molding the Planet 5 (2016):63–70.Google Scholar

Ellis, EC, Magliocca, NR, Stevens, CJ, et al. Evolving the Anthropocene: Linking multi-level selection with long-term social–ecological change. Sustainability Science 13.1 (2018):119–128.Google Scholar

IPCC (Intergovernmental Panel on Climate Change). Summary for Policy Makers. In Global warming of 1.5°C. An IPCC special report on the impacts of global warming of 1.5 °C above pre-industrial levels and related global greenhouse gas emission pathways. World Meteorological Organization, 2018.Google Scholar

Ripple, WJ, Wolf, C, Newsome, TM, et al. World scientists’ warning to humanity: A second notice. BioScience 67.12 (2017):1026–1028.Google Scholar

Foley, RA. Speciation, extinction and climatic change in hominid evolution. Journal of Human Evolution 26.4 (1994):275–289.Google Scholar

Gamble, C, Davies, W, Pettitt, P, et al. Climate change and evolving human diversity in Europe during the last glacial. Willis, KJ, Bennett, KD, Walker, D, eds. Philosophical Transactions of the Royal Society B: Biological Sciences 359.1442 (2004):243–254.Google Scholar

Potts, R. Environmental and behavioral evidence pertaining to the evolution of early homo. Current Anthropology 53.S6 (2012):S299–S317.Google Scholar

Scarborough, VL. Human niches, abandonment cycling, and climates. Water History 7.4 (2015):381–396.Google Scholar

Steffen, W, Broadgate, W, Deutsch, L, et al. The trajectory of the Anthropocene: The great acceleration. The Anthropocene Review 2.1 (2015):81–98.CrossRefGoogle Scholar

Rockström, J, Steffen, W, Noone, K, et al. A safe operating space for humanity. Nature 461.7263 (2009):472–475.Google Scholar

NOAA (National Oceanic and Atmospheric Administration). Global Monitoring Laboratory: Earth Systems Research Laboratory – carbon cycle greenhouse gases. National Oceanic and Atmospheric Administration, 2021 [cited October 14, 2021] p. 7. Available from: https://gml.noaa.gov/ccgg/trends/global.htmlGoogle Scholar

Landrigan, PJ, Fuller, R, Acosta, NJR, et al. The Lancet Commission on pollution and health. The Lancet 391.10119 (2017):462–512.Google Scholar

Lee, K, Greenstone, M. Air Quality Life Index annual report: 2021. Energy Policy Institute at the University of Chicago, 2021 [cited October 13, 2021] p. 15. Available from: https://aqli.epic.uchicago.edu/wp-content/uploads/2021/08/AQLI_2021-Report.EnglishGlobal.pdfGoogle Scholar

WHO (World Health Organization). Global Ambient Air Pollution Summary Results. WHO, 2017, p. 6.Google Scholar

Boyle, K, Örmeci, B. Microplastics and nanoplastics in the freshwater and terrestrial environment: A review. Water 12.9 (2020):2633.Google Scholar

Choy, CA, Robison, BH, Gagne, TO, et al. The vertical distribution and biological transport of marine microplastics across the epipelagic and mesopelagic water column. Scientific Reports 9.1 (2019):7843.Google Scholar

Allen, S, Allen, D, Phoenix, VR, et al. Atmospheric transport and deposition of microplastics in a remote mountain catchment. Nature Geoscience 12 (2019):339–344.Google Scholar

Chen, H, Hua, X, Yang, Y, et al. Chronic exposure to UV-aged microplastics induces neurotoxicity by affecting dopamine, glutamate, and serotonin neurotransmission in Caenorhabditis elegans. Journal of Hazardous Materials 419 (2021):126482.Google Scholar

Smith, M, Love, DC, Rochman, CM, et al. Microplastics in seafood and the implications for human health. Current Environmental Health Reports 5.3 (2018):375–386.Google Scholar

WHO (World Health Organization). World Health Statistics. Geneva: WHO, 2019, p. 213.Google Scholar

World Bank. Life expectancy at birth, total (years): Data. The World Bank, 2020 [cited October 14, 2021] p. 3. Available from: https://data.worldbank.org/indicator/SP.DYN.LE00.INGoogle Scholar

Burnett, R, Chen, H, Szyszkowicz, M, et al. Global estimates of mortality associated with long-term exposure to outdoor fine particulate matter. PNAS 115.38 (2018):9592–9597.Google Scholar

Vohra, K, Vodonos, A, Schwartz, J, et al. Global mortality from outdoor fine particle pollution generated by fossil fuel combustion: Results from GEOS-Chem. Environmental Research 195 (2021):110754.Google Scholar

Gehring, U, Wijga, AH, Hoek, G, et al. Exposure to air pollution and development of asthma and rhinoconjunctivitis throughout childhood and adolescence: A population-based birth cohort study. The Lancet Respiratory Medicine 3.12 (2015):933–942.Google Scholar

Rees, N, UNICEF. Clear the Air for the Children: The Impact of Air Pollution on Children. New York: UNICEF, 2016.Google Scholar

Smith, RB, Fecht, D, Gulliver, J, et al. Impact of London’s road traffic air and noise pollution on birth weight: Retrospective population based cohort study. BMJ 359 (2017):j5299.Google Scholar

Stieb, DM, Chen, L, Eshoul, M, et al. Ambient air pollution, birth weight and preterm birth: A systematic review and meta-analysis. Environmental Research 117 (2012):100–111.Google Scholar

Zhang, X, Chen, X, Zhang, X. The impact of exposure to air pollution on cognitive performance. PNAS 115.37 (2018):9193–9197.Google Scholar

WHO (World Health Organization). Global Health Observatory Data Repository. WHO, 2016.Google Scholar

WHO (World Health Organization). WHO global air quality guidelines: Particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide. World Health Organization, 2021 [cited September 23, 2021]. Available from: https://apps.who.int/iris/handle/10665/345329Google Scholar

Vermeulen, R, Schymanski, EL, Barabási, A-L, et al. The exposome and health: Where chemistry meets biology. Science 367.6476 (2020):392–396.Google Scholar

Dursun, A, Yurdakok, K, Yalcin, SS, et al. Maternal risk factors associated with lead, mercury and cadmium levels in umbilical cord blood, breast milk and newborn hair. The Journal of Maternal-Fetal & Neonatal Medicine 29.6 (2016):954–961.Google Scholar

Morello-Frosch, R, Cushing, LJ, Jesdale, BM, et al. Environmental chemicals in an urban population of pregnant women and their newborns from San Francisco. Environmental Science & Technology 50.22 (2016):12464–12472.Google Scholar

Watts, N, Adger, N, Zhang, Q, et al. Health and climate change: Policy responses to protect public health. The Lancet 386 (2015):1861–1914.Google Scholar

Watts, N, Amann, M, Ayeb-Karlsson, S, et al. The Lancet Countdown on health and climate change: From 25 years of inaction to a global transformation for public health. The Lancet 391.101200 (2017):581–630[cited November 3, 2017]. Available from: http://linkinghub.elsevier.com/retrieve/pii/S0140673617324649Google Scholar

Garner, AJ, Mann, ME, Emanuel, KA, et al. Impact of climate change on New York City’s coastal flood hazard: Increasing flood heights from the preindustrial to 2300 CE. PNAS 114.45 (2017):11861–11866.Google Scholar

Hirabayashi, Y, Mahendran, R, Koirala, S, et al. Global flood risk under climate change. Nature Climate Change 3.9 (2013): 816–821.Google Scholar

Winsemius, HC, Jongman, B, Veldkamp, TIE, et al. Disaster risk, climate change, and poverty: Assessing the global exposure of poor people to floods and droughts. Environment and Development Economics 23.3 (2018):328–348.Google Scholar

Balaguru, K, Judi, DR, Leung, LR. Future hurricane storm surge risk for the U.S. Gulf and Florida coasts based on projections of thermodynamic potential intensity. Climatic Change 138.1–2 (2016):99–110.Google Scholar

Collins, JM, Walsh, K, eds. Hurricanes and Climate Change. Cham: Springer International Publishing, 2017.Google Scholar

Trenberth, KE, Cheng, L, Jacobs, P, et al. Hurricane Harvey links to ocean heat content and climate change adaptation. Earth’s Future 6.5 (2018): 730–744.Google Scholar

Abatzoglou, JT, Williams, AP. Impact of anthropogenic climate change on wildfire across western US forests. PNAS 113.42 (2016):11770–11775.Google Scholar

Fried, JS, Torn, MS, Mills, E. The impact of climate change on wildfire severity: A regional forecast for northern California. Climatic Change 64.1–2 (2004):169–191.CrossRefGoogle Scholar

Liu, Y, Goodrick, SL, Stanturf, J. Future U.S. wildfire potential trends projected using a dynamically downscaled climate change scenario. Forest Ecology and Management 294 (2013):120–135.Google Scholar

Marlon, JR, Bartlein, PJ, Walsh, MK, et al. Wildfire responses to abrupt climate change in North America. PNAS 106.8 (2009): 2519–2524.Google Scholar

Mann, ME, Rahmstorf, S, Kornhuber, K, et al. Influence of anthropogenic climate change on planetary wave resonance and extreme weather events. Scientific Reports 7 (2017):45242.Google Scholar

Kishore, N, Marqués, D, Mahmud, A, et al. Mortality in Puerto Rico after Hurricane Maria. New England Journal of Medicine 379.2 (2018):162–170.Google Scholar

Smith, A, Lott, N, Houston, T, et al. U.S. Billion-Dollar Weather and Climate Disasters 1980–2018. NOAA National Center for Environmental Information, 2018, pp. 1–14.Google Scholar

Bacmeister, JT, Reed, KA, Hannay, C, et al. Projected changes in tropical cyclone activity under future warming scenarios using a high-resolution climate model. Climatic Change 146.3–4 (2018):547–560.Google Scholar

Bindoff, NL, Stott, PA, AchutaRao, KM, et al. Detection and attribution of climate change: From global to regional. In Stocker, TF, Plattner, GK, Tignor, M, eds. Climate Change 2013: The Physical Science Basis Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, 2013, pp. 867–952.Google Scholar

Cornwall, E. Efforts to link climate change to severe weather gain ground. Science 351.6279 (2016):1249–1252.CrossRefGoogle ScholarPubMed

Field, CB, Barros, VR, Mastrandrea, MD, et al. Summary for Policymakers. Climate Change 2014: Impacts, Adaptation, and Vulnerability Part A: Global and Sectoral Aspects Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. IPCC, 2014, pp. 1–32.Google Scholar

Otto, F, James, R, Allen, M. The Science of Attributing Extreme Weather Events and Its Potential Contribution to Assessing Loss and Damage Associated with Climate Change Impacts. Environmental Change Institute, 2014, pp. 1–4.Google Scholar

Trenberth, KE. Framing the way to relate climate extremes to climate change. Climatic Change 115.2 (2012):283–290.Google Scholar

Trenberth, KE, Fasullo, JT, Shepherd, TG. Attribution of climate extreme events. Nature Climate Change 5.8 (2015):725–730.Google Scholar

Otto, FEL. Attribution of weather and climate events. Annual Review of Environment and Resources 42.1 (2017):627–646.Google Scholar

Meadows, D. Thinking in Systems: A Primer. Chelsea Green Publishing, 2008.Google Scholar

Fuentes, A. The extended evolutionary synthesis, ethnography, and the human niche: Toward an integrated anthropology. Current Anthropology 57. S13 (2016):S13–S26.Google Scholar

Kendal, JR, Tehrani, JJ, Odling-Smee, J. Human niche construction in interdisciplinary focus. Philosophical Transactions of the Royal Society B: Biological Sciences 366.1566 (2011):785–792.Google Scholar

Costanza, R. A theory of socio-ecological system change. Journal of Bioeconomics 16.1 (2014):39–44.Google Scholar

Cote, M, Nightingale, AJ. Resilience thinking meets social theory: Situating social change in socio-ecological systems (SES) research. Progress in Human Geography 36.4 (2012):475–489.Google Scholar

Young, OR, Berkhout, F, Gallopin, GC, et al. The globalization of socio-ecological systems: An agenda for scientific research. Global Environmental Change 16.3 (2006):304–316.Google Scholar

Alberti, M, Asbjornsen, H, Baker, LA, et al. Research on coupled human and natural systems (CHANS): Approach, challenges, and strategies. The Bulletin of the Ecological Society of America 92.2 (2011):218–228.Google Scholar

Liu, J, Dietz, T, Carpenter, SR, et al. Coupled human and natural systems. ambi 36.8 (2007):639–649.Google Scholar

Liu, J, Dietz, T, Carpenter, SR, et al. Complexity of coupled human and natural systems. Science 317.5844 (2007):1513–1516.Google Scholar

Mora, C, Spirandelli, D, Franklin, EC, et al. Broad threat to humanity from cumulative climate hazards intensified by greenhouse gas emissions. Nature Climate Change 8.12 (2018):1062–1071.Google Scholar

Alexeeff, GV, Faust, JB, August, LM, et al. A screening method for assessing cumulative impacts. International Journal of Environmental Research and Public Health 9.2 (2012):648–659.Google Scholar

Neri, AC, Dupin, P, Sánchez, LE. A pressure–state–response approach to cumulative impact assessment. Journal of Cleaner Production 126 (2016):288–298.Google Scholar

Fuentes, A. Why We Believe: Evolution and the Human Way of Being. Yale University Press, 2019.Google Scholar

Ptolemy, . Ptolemy’s Almagest. Translated by GJ Toomer. Springer-Verlag, 1984.Google Scholar

Bell, L. Climate of Corruption: Politics and Power Behind the Global Warming Hoax. Greenleaf Book Group, 2011.Google Scholar

Cilliers, P. Complexity and Postmodernism: Understanding Complex Systems. Psychology Press, 1998.Google Scholar

Cilliers, P. Boundaries, hierarchies and networks in complex systems. International Journal of Innovation Management 05.02 (2001):135–147.Google Scholar

Cilliers, P. Complexity, deconstruction and relativism. Theory, Culture & Society 22.5 (2005):255–267.Google Scholar

de Coning, C. From peacebuilding to sustaining peace: Implications of complexity for resilience and sustainability. Resilience 4.3 (2016):166–181.Google Scholar

Dalby, S. Environmental (in)security. In Richardson, D, Castree, N, Goodchild, MF, Kobayashi, A, Liu, W, Marston, MA, eds. International Encyclopedia of Geography. American Cancer Society, 2017 [cited August 27, 2019] pp. 1–10. Available from: https://onlinelibrary.wiley.com/doi/abs/10.1002/9781118786352.wbieg0428Google Scholar

Dalby, S. Anthropocene formations: Environmental security, geopolitics and disaster. Theory, Culture & Society 34.2–3 (2017):233–252.Google Scholar

Nielsen, KS, Clayton, S, Stern, PC, et al. How psychology can help limit climate change. American Psychologist 76.1 (2021):130–144.Google Scholar

Steg, L. Values, norms, and intrinsic motivation to act proenvironmentally. Annual Review of Environment and Resources 41.1 (2016):277–292.Google Scholar

Oreskes, N, Conway, EM. The Collapse of Western Civilization: A View from the Future. Columbia University Press, 2014.Google Scholar

Kolbert, E. The Sixth Extinction: An Unnatural History. Henry Holt and Company, 2014.Google Scholar

Odling-Smee, J, Erwin, DH, Palkovacs, EP, et al. Niche construction theory: A practical guide for ecologists. The Quarterly Review of Biology 88.1 (2013):3–28.Google Scholar

Antón, SC, Kuzawa, CW. Early homo, plasticity and the extended evolutionary synthesis. Interface Focus 7.5 (2017):20170004.Google Scholar

Danchin, É, Charmantier, A, Champagne, FA, et al. Beyond DNA: Integrating inclusive inheritance into an extended theory of evolution. Nature Reviews Genetics 12.7 (2011):475–486.Google Scholar

Pigliucci, M, Müller, G, eds. Evolution, The Extended Synthesis. MIT Press, 2010.Google Scholar

Flynn, EG, Laland, KN, Kendal, RL, et al. Developmental niche construction. Developmental Science 16 (2013):296–313.Google Scholar

Laland, K, Matthews, B, Feldman, MW. An introduction to niche construction theory. Evolutionary Ecology 30.2 (2016):191–202.Google Scholar

Laland, KN, Boogert, N, Evans, C. Niche construction, innovation and complexity. Environmental Innovation and Societal Transitions 11 (2014):71–86.Google Scholar

Huxley, J, Pigliucci, M, Müller, GB. Evolution: The Modern Synthesis: The Definitive Edition. MIT Press, 2010.Google Scholar

Fuentes, A. The Creative Spark: How Imagination Made Humans Exceptional. Penguin, 2017.Google Scholar

Kuzawa, CW, Bragg, JM. Plasticity in human life history strategy: Implications for contemporary human variation and the evolution of genus. Current Anthropology 53. S6 (2012):S369–S382.Google Scholar

Odling-Smee, J, Laland, KN. Ecological inheritance and cultural inheritance: What are they and how do they differ? Philosophical Transactions of the Royal Society B: Biological Sciences 6.366 (2011):785–792.Google Scholar

Fuentes, A. Integrative anthropology and the human niche: Toward a contemporary approach to human evolution, integrative anthropology and the human niche. American Anthropologist 117.2 (2015):302–315.Google Scholar

Sullivan, AP, Bird, DW, Perry, GH. Human behaviour as a long-term ecological driver of non-human evolution. Nature Ecology & Evolution 1.3 (2017):0065.Google Scholar

Kieffer, SW. The Dynamics of Disaster. W. W. Norton & Company, 2013.Google Scholar

Constant, A, Ramstead, MJD, Veissière, SPL, et al. A variational approach to niche construction. Journal of the Royal Society Interface 15.141 (2018):20170685.Google Scholar

Scott-Phillips, TC, Laland, KN, Shuker, DM, et al. The niche construction perspective: A critical appraisal. Evolution 68.5 (2014):1231–1243.Google Scholar

Dawkins, R. Extended phenotype – but not too extended: A reply to Laland, Turner and Jablonka. Biology & Philosophy 19.3 (2004):377–396.Google Scholar

New World. Petroleum. In New World Encyclopedia, New World Encyclopedia, 2019 [cited May 21, 2019]. Available from: www.newworldencyclopedia.org/entry/Petroleum#HistoryGoogle Scholar

Coumou, D, Rahmstorf, S. A decade of weather extremes. Nature Climate Change 2.7 (2012):491–496.Google Scholar

IEP (Ecological Threat Register). Ecological threat register 2020: Understanding ecological threats, resilience and peace. Institute for Economics and Peace, 2020 [cited September 11, 2020] p. 95. Available from: https://visionofhumanity.org/wp-content/uploads/2020/10/ETR_2020_web-1.pdfGoogle Scholar

IPCC (International Panel on Climate Change). IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. International Panel on Climate Change, 2019, p. 1170.Google Scholar

IPCC (International Panel on Climate Change). Climate Change and Land: An IPCC Special Report on Climate Change, Desertification, Land Degradation, Sustainable Land Management, Food Security, and Greenhouse Gas Fluxes In Terrestrial Ecosystems. International Panel on Climate Change, 2019, p. 43.Google Scholar

Kulp, SA, Strauss, BH. New elevation data triple estimates of global vulnerability to sea-level rise and coastal flooding. Nature Communications 10.1 (2019):1–12.Google Scholar

Mora, C, Dousset, B, Caldwell, IR, et al. Global risk of deadly heat. Nature Climate Change 7.7 (2017):501–506.Google Scholar

Raymond, C, Matthews, T, Horton, RM. The emergence of heat and humidity too severe for human tolerance. Science Advances 6.19 (2020):eaaw1838.Google Scholar

Swain, DL, Singh, D, Touma, D, et al. Attributing extreme events to climate change: A new frontier in a warming world. One Earth 2.6 (2020):522–527.Google Scholar

Keellings, D, Ayala, JJH. Extreme rainfall associated with Hurricane Maria over Puerto Rico and its connections to climate variability and change. Geophysical Research Letters 46.5 (2019):2964–2973.Google Scholar

Lanier, C, Deram, A, Cuny, M-A, et al. Spatial analysis of environmental inequalities caused by multiple air pollutants: A cumulative impact screening method, applied to the north of France. Ecological Indicators 99 (2019):91–100.Google Scholar

US EPA (Environmental Protection Agency). Consideration of cumulative impacts. US Environmental Protection Agency, 1999. Available from: www.epa.gov/sites/production/files/2014-08/documents/cumulative.pdfGoogle Scholar

Wild, CP. The exposome: From concept to utility. International Journal of Epidemiology 41.1 (2012):24–32.Google Scholar

US EPA (Environmental Protection Agency). Framework for Human Health Risk Assessment to Inform Decision Making. US Environmental Protection Agency, 2014, p. 76.Google Scholar

US EPA (Environmental Protection Agency). Criteria air pollutants. US Environmental Protection Agency, 2021 [cited March 10, 2021] p. 3. Available from: www.epa.gov/criteria-air-pollutantsGoogle Scholar

US EPA (Environmental Protection Agency). Hazardous air pollutants. US Environmental Protection Agency, 2021 [cited March 10, 2021] p. 3. Available from: www.epa.gov/hapsGoogle Scholar

US EPA (Environmental Protection Agency). Overview of greenhouse gases. US Environmental Protection Agency, 2015 [cited March 10, 2021] p. 13. Available from: www.epa.gov/ghgemissions/overview-greenhouse-gasesGoogle Scholar

Davies, T. Toxic space and time: Slow violence, necropolitics, and petrochemical pollution. Annals of the American Association of Geographers 108.6 (2018):1537–1553.Google Scholar

Kallis, G, Kostakis, V, Lange, S, et al. Research on degrowth. Annual Review of Environment and Resources 43.1 (2018):291–316.Google Scholar

Martínez-Alier, J. Environmental justice and economic degrowth: An alliance between two movements. Capitalism Nature Socialism 23.1 (2012):51–73.Google Scholar

Nixon, R. Slow violence, gender, and the environmentalism of the poor. Journal of Commonwealth and Postcolonial Studies 13.2–14.1 (2007):14–37.Google Scholar

Dalby, S. Biopolitics and climate security in the Anthropocene. Geoforum 49 (2013):184–192.Google Scholar

Dalby, S. Recontextualising violence, power and nature: The next twenty years of critical geopolitics? Political Geography 29.5 (2010):280–288.Google Scholar

Calderón-Garcidueñas, L, Gónzalez-Maciel, A, Reynoso-Robles, R, et al. Hallmarks of Alzheimer disease are evolving relentlessly in Metropolitan Mexico City infants, children and young adults: APOE4 carriers have higher suicide risk and higher odds of reaching NFT stage V at ≤ 40 years of age. Environmental Research 164 (2018):475–487.Google Scholar

Dalby, S. Firepower: Geopolitical cultures in the Anthropocene. Geopolitics 23.3 (2018):718–742.Google Scholar

Nixon, R. Slow Violence and the Environmentalism of the Poor. Harvard University Press, 2011.Google Scholar

Pope, A, Lefler Jacob, S, Ezzati, M, et al. Mortality risk and fine particulate air pollution in a large, representative cohort of U.S. adults. Environmental Health Perspectives 127.7 (2020):077007.Google Scholar

Shehab, MA, Pope, FD. Effects of short-term exposure to particulate matter air pollution on cognitive performance. Scientific Reports 9.1 (2019):1–10.Google Scholar

Banzhaf, S, Ma, L, Timmins, C. Environmental justice: The economics of race, place, and pollution. Journal of Economic Perspectives 33.1 (2019):185–208.Google Scholar

Jorgenson, AK. Environment, development, and ecologically unequal exchange. Sustainability 8.3 (2016):227.Google Scholar

Kallis, G. Socialism without growth. Capitalism Nature Socialism 30.2 (2019):189–206.Google Scholar

Shrader-Frechette, K. Environmental Justice: Creating Equality, Reclaiming Democracy. Oxford University Press, 2002.Google Scholar

Shrader-Frechette, K. Taking Action, Saving Lives: Our Duties to Protect Environmental and Public Health. Oxford University Press, 2007.Google Scholar

Ellis, EC, Ramankutty, N. Putting people in the map: Anthropogenic biomes of the world. Frontiers in Ecology and the Environment 6.8 (2008):439–447.Google Scholar

Steffen, W, Persson, Å, Deutsch, L, et al. The Anthropocene: From global change to planetary stewardship. AMBIO 40.7 (2011):739–761.Google Scholar

Cohen, AJ, Anderson, HR, Ostro, B, et al. The global burden of disease due to outdoor air pollution. Journal of Toxicology and Environmental Health, Part A 68.13–14 (2005):1301–1307.Google Scholar

Cohen, AJ, Brauer, M, Burnett, R, et al. Estimates and 25-year trends of the global burden of disease attributable to ambient air pollution: An analysis of data from the Global Burden of Diseases Study 2015. The Lancet 389.10082 (2017):1907–1918.Google Scholar

Watts, N, Amann, M, Ayeb-Karlsson, S, et al. The Lancet Countdown on health and climate change: From 25 years of inaction to a global transformation for public health. The Lancet S0140–6736.17 (2017):32464–32469.Google Scholar

Galtung, J. A structural theory of aggression. Journal of Peace Research 1.2 (1964):95–119.Google Scholar

Galtung, J. Institutionalized conflict resolution: A theoretical paradigm. Journal of Peace Research 2.4 (1965):348–397.Google Scholar

Galtung, J. A structural theory of integration. Journal of Peace Research 5.4 (1968):375–395.Google Scholar

Richmond, OP. Peace: A Very Short Introduction. 1st ed. Oxford University Press, 2014.Google Scholar

Wallensteen, P. Strategic peacebuilding: Concepts and challenges. In Philpott, D, Powers, GF, eds. Strategies of Peace. Oxford University Press, 2010, pp. 45–64.Google Scholar

Wallensteen, P. Quality Peace. Oxford University Press, 2013.Google Scholar

Galtung, J. Cultural violence. Journal of Peace Research 27.3 (1990):291–305.Google Scholar

Galtung, J. Violence, peace, and peace research. Journal of Peace Research 6.3 (1969):167–191.Google Scholar

Farmer, P. An anthropology of structural violence. Current Anthropology 45.3 (2004):305–325.Google Scholar

Springs, JA. Structural and cultural violence in religion and peacebuilding. In Omer, A, Scott Appleby, R, Little, D, eds. The Oxford Handbook of Religion, Conflict, and Peacebuilding. Oxford University Press, 2015, p. 146.Google Scholar

Wiegert, K. Structural violence. In Fink, G, ed. Stress of War, Conflict and Disaster. Academic Press, 2010, pp. 126–133.Google Scholar

Bourdieu, P. Masculine Domination. Stanford University Press, 1998.Google Scholar

Heise, L, Ellsberg, M, Gottmoeller, M. A global overview of gender-based violence. International Journal of Gynecology & Obstetrics 78. S1 (2002):S5–S14.Google Scholar

Reed, E, Raj, A, Miller, E, et al. Losing the “gender” in gender-based violence: The missteps of research on dating and intimate partner violence. Violence Against Women 16.3 (2010):348–354.Google Scholar

García-Moreno, C, Pallitto, C, Devries, K, et al. Global and Regional Estimates of Violence against Women: Prevalence and Health Effects of Intimate Partner Violence and Non-Partner Sexual Violence. World Health Organization, 2013.Google Scholar

Jewkes, R, Sen, P, Garcia-Moreno, C, et al. Sexual violence. In Sen, P, Garcia-Moreno, C, eds. International Encyclopedia of Public Health. Elsevier, 2017, pp. 491–498.Google Scholar

Graham-Bermann, SA, Howell, KH, Miller, LE, et al. Traumatic events and maternal education as predictors of verbal ability for preschool children exposed to intimate partner violence (IPV). Journal of Family Violence 25.4 (2010):383–392.Google Scholar

Miller, LE, Howell, KH, Graham-Bermann, SA. The effect of an evidence-based intervention on women’s exposure to intimate partner violence. American Journal of Orthopsychiatry 84.4 (2014):321–328.Google Scholar

Bourdieu, P, Wacquant, L. Symbolic violence. In Scheper-Hughes, N, Bourgois, P, eds. Violence in War and Peace. Blackwell Publishing, 2004, pp. 272–275.Google Scholar

Bourdieu, P. Outline of a Theory of Practice. Cambridge University Press, 1972.Google Scholar

Bourdieu, P. Pascalian Meditations. Stanford University Press, 2000.Google Scholar

Kendal, JR. Cultural niche construction and human learning environments: Investigating sociocultural perspectives. Biol Theory 6.3 (2011):241–250.Google Scholar

Anenberg, SC, Horowitz, LW, Tong, DQ, et al. An estimate of the global burden of anthropogenic ozone and fine particulate matter on premature human mortality using atmospheric modeling. Environmental Health Perspectives 118.9 (2010):1189–1195.Google Scholar

Adger, N. Vulnerability. Global Environmental Change 16.3 (2006):268–281.Google Scholar

Blaikie, P, Cannon, T, Davis, I, et al. At Risk: Natural Hazards, People’s Vulnerability and Disasters. Routledge, 2014.Google Scholar

Kammen, DM, Hassenzahl, DM. Should We Risk It? Exploring Environmental, Health, and Technological Problem Solving. Princeton University Press, 2001.Google Scholar

Cardona, O. The need for rethinking the concepts of vulnerability and risk from a holistic perspective. In Bankoff, G, Hilhorst, D, Frerks, G, eds. Mapping Vulnerability. Earthscan, 2004, pp. 37–52.Google Scholar

Beck, U. World Risk Society. Wiley, 1999.Google Scholar

Oliver-Smith, A. Disaster risk reduction and climate change adaptation: The view from applied anthropology. Human Organization 72.4 (2013):275–282.Google Scholar

Barnett, J, Adger, N. Climate change, human security and violent conflict. Political Geography 26.6 (2007):639–655.Google Scholar

Adger, N. Climate change, human well-being and insecurity. New Political Economy 15.2 (2010):275–292.Google Scholar

Adger, N, Pulhin, JM, Barnett, J, et al. Human security. In Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. In Human Security. Cambridge University Press, 2014, pp. 755–791.Google Scholar

Adger, N, Barnett, J, Chapin III, FS, et al. This must be the place: Underrepresentation of identity and meaning in climate change decision-making. Global Environmental Politics 11.2 (2011):1–25.Google Scholar

Oliver-Smith, A. Anthropological research on hazards and disasters. Annual Review of Anthropology 25.1 (1996):303–328.Google Scholar

Oliver-Smith, A. Disaster risk reduction and applied anthropology. Annals of Anthropological Practice 40.1 (2016):73–85.Google Scholar

Wisner, B. Assessment of capability and vulnerability. In Bankoff, G, Hilhorst, D, Frerks, G, eds. Mapping Vulnerability. Earthscan, 2004, pp. 186–197.Google Scholar

Goymann, W, Küblbeck, M. The second warning to humanity: Why ethology matters? Bshary, R, ed. Ethology 126.1 (2020):1–9.Google Scholar

Barnett, J, Tschakert, P, Head, L, et al. A science of loss. Nature Clim Change 6.11 (2016):976–978.Google Scholar

McShane, K. Values and harms in loss and damage. Ethics, Policy & Environment 20.2 (2017):129–142.Google Scholar

Tschakert, P, Oort, B van, Clair, ALS, et al. Inequality and transformation analyses: A complementary lens for addressing vulnerability to climate change. Climate and Development 5.4 (2013):340–350.Google Scholar

Tschakert, P, Barnett, J, Ellis, N, et al. Climate change and loss, as if people mattered: Values, places, and experiences. WIREs Climate Change 8.5 (2017):e476.Google Scholar

Kirsch, S. Reverse Anthropology: Indigenous Analysis of Social and Environmental Relations in New Guinea. Stanford University Press, 2006.Google Scholar

Tschakert, P, Dietrich, KA. Anticipatory learning for climate change adaptation and resilience. Ecology and Society 15.2 (2010):11.Google Scholar

Adger, N, de Campos, RS, Siddiqui, T, et al. Human security of urban migrant populations affected by length of residence and environmental hazards. Journal of Peace Research 58.1 (2021):50–66.Google Scholar

Millar, G. Ambition and ambivalence: Reconsidering positive peace as a trans-scalar peace system. Journal of Peace Research 58.4 (2021):640–654.Google Scholar

Millar, G. Coordinated ethnographic peace research: Assessing complex peace interventions writ large and over time. Peacebuilding 9.2 (2021):145–159.Google Scholar

de Coning, C. Adaptive peace operations: Navigating the complexity of influencing societal change without causing harm. International Peacekeeping 27.5 (2020):836–858.Google Scholar

de Coning, C. Insights from complexity theory for peace and conflict studies. In Richmond, O, Visoka, G, eds. The Palgrave Encyclopedia of Peace and Conflict Studies. Springer International Publishing, 2020 [cited November 1, 2021] pp. 1–10. Available from: https://doi.org/10.1007/978-3-030-11795-5_134-1Google Scholar

Farmer, P. On suffering and structural violence: A view from below. Daedalus 125.1 (1996):261–283.Google Scholar

Weigert, KM. Structural violence. In Kurtz, L, ed. Encyclopedia of Violence, Peace, and Conflict. 3rd ed. Elsevier, 2008, pp. 2004–2011.Google Scholar

Ricigliano, R. Making Peace Last: A Toolbox for Sustainable Peacebuilding. Routledge, 2015 [cited August 20, 2019]. Available from: www.taylorfrancis.com/books/9781315633565Google Scholar

Gay, WC. The role of language in justifying and eliminating cultural violence. In Gursozlu, F, ed. Peace, Culture, and Violence. Brill, 2018, pp. 31–63.Google Scholar

Taylor, JY. No resting place: African American women at the crossroads of violence. Violence Against Women 11.12 (2005):1473–1489.Google Scholar

Oliver, W. Cultural racism and structural violence. Journal of Human Behavior in the Social Environment 4.2–3 (2001):1–26.Google Scholar

Wimmer, A, Schetter, C. Ethnic violence. In Heitmeyer, W, Hagan, J, eds. International Handbook of Violence Research. Springer Netherlands, 2003 [cited October 15, 2021] pp. 247–260. Available from: https://doi.org/10.1007/978-0-306-48039-3_13Google Scholar

Fearon, JD, Laitin, DD. Violence and the social construction of ethnic identity. International Organization 54.4 (2000):845–877.Google Scholar

US EPA (Environmental Protection Agency). Population Surrounding 1,836 Superfund Remedial Sites. United States Environmental Protection Agency, 2017, p. 3.Google Scholar

US EPA (Environmental Protection Agency). Population surrounding US EPA superfund, RCRA CA, and brownfield sites. US Environmental Protection Agency, 2017 [cited February 5, 2019]. Available from: www.epa.gov/sites/production/files/2015-09/documents/weballsites9.28.15.pdfGoogle Scholar

US EPA (Environmental Protection Agency). Cleanups in my community: Cleaning up our land, water and air digital database. US Environmental Protection Agency, 2021 [cited July 11, 2019]. Available from: https://ofmpub.epa.gov/apex/cimc/f?p=cimc:map:0:::71Google Scholar

Landrigan, PJ, Fuller, R, Hu, H, et al. Pollution and global health: An agenda for prevention. Environmental Health Perspectives 126.8 (2018):1–6.Google Scholar

Lelieveld, J, Evans, JS, Fnais, M, et al. The contribution of outdoor air pollution sources to premature mortality on a global scale. Nature 525.7569 (2015):367–371.Google Scholar

Crist, E, Mora, C, Engelman, R. The interaction of human population, food production, and biodiversity protection. Science 356.6335 (2017):260–264.Google Scholar

Payne, RJ, Dise, NB, Stevens, CJ, et al. Impact of nitrogen deposition at the species level. Proceedings of the National Academy of Sciences 110.3 (2013):984–987.Google Scholar

Posthuma, L, van Gils, J, Zijp, MC. Species sensitivity distributions for use in environmental protection, assessment, and management of aquatic ecosystems for 12 386 chemicals. Environmental Toxicology and Chemistry 38.4 (2019):905–917.Google Scholar

Tang, Z, Huang, Q, Nie, Z, et al. Pollution threatens migratory shorebirds. Science 350.6265 (2015):1176–1177.Google Scholar

WWF (World Worldlife Fund). Living planet report for 2020: Bending the curve of biodiversity loss. World Wildlife Fund, 2020 [cited September 14, 2020] p. 83. Available from: www.zsl.org/sites/default/files/LPR%202020%20Full%20report.pdfGoogle Scholar

US EPA (Environmental Protection Agency). Our mission and what we do. US Environmental Protection Agency, 2013 [cited July 26, 2019]. Available from: www.epa.gov/aboutepa/our-mission-and-what-we-doGoogle Scholar

Myers, S, Frumkin, H. Planetary Health: Protecting Nature to Protect Ourselves. Island Press, 2020.Google Scholar

Whitmee, S, Haines, A, Beyrer, C, et al. Safeguarding human health in the Anthropocene epoch: Report of the Rockefeller Foundation–Lancet Commission on planetary health. The Lancet 386.10007 (2015):1973–2028.Google Scholar

Haines, A, Frumkin, H. Planetary Health: Safeguarding Human Health and the Environment in the Anthropocene. Cambridge University Press, 2021 [cited June 24, 2021]. Available from: www.cambridge.org/core/books/planetary-health/33E5DF80318C63C41606E106FF85D99DGoogle Scholar

Brooks, P. Rachel Carson: The Writer at Work. Sierra Club Books, 1998.Google Scholar

Neukom, R, Barboza, L, Erb, M, et al. Consistent multidecadal variability in global temperature reconstructions and simulations over the Common Era. Nature Geoscience 1 (2019).Google Scholar

Breitburg, DL, Salisbury, J, Bernhard, JM, et al. And on top of all that …: Coping with ocean acidification in the midst of many stressors. Oceanography 28.2 (2015):48–61.Google Scholar

Doney, SC, Fabry, VJ, Feely, RA, et al. Ocean acidification: The other CO₂ problem. Annual Review of Marine Science 1.1 (2009):169–192.Google Scholar

Hoegh-Guldberg, O, Bruno, JF. The impact of climate change on the world’s marine ecosystems. Science 328.5985 (2010):1523–1528.Google Scholar

Bhatia, KT, Vecchi, GA, Knutson, TR, et al. Recent increases in tropical cyclone intensification rates. Nature Communications 10.1 (2019):1–9.Google Scholar

Kossin, JP. A global slowdown of tropical-cyclone translation speed. Nature 558.7708 (2018):104–107.Google Scholar

Otto, FEL, Skeie, RB, Fuglestvedt, JS, et al. Assigning historic responsibility for extreme weather events. Nature Climate Change 7.11 (2017):757–759.Google Scholar

US EPA (Environmental Protection Agency). Learn about dioxin. US Environmental Protection Agency, 2014 [cited March 10, 2021] p. 7. Available from: www.epa.gov/dioxin/learn-about-dioxinGoogle Scholar

GAHP (Global Alliance on Health and Pollution). Pollution Health Overview and Solutions. Global Alliance on Health and Pollution, 2019, p. 5.Google Scholar

Watts, N, Amann, M, Arnell, N, et al. The 2019 report of The Lancet Countdown on health and climate change: Ensuring that the health of a child born today is not defined by a changing climate. The Lancet 394.10211 (2019):1836–1878.Google Scholar

Hawken, P. Regeneration: Ending the Climate Crisis in One Generation. Penguin, 2021.Google Scholar

Füssel, H-M. Vulnerability: A generally applicable conceptual framework for climate change research. Global Environmental Change 17.2 (2007):155–167.Google Scholar

Marsooli, R, Lin, N, Emanuel, K, et al. Climate change exacerbates hurricane flood hazards along US Atlantic and Gulf coasts in spatially varying patterns. Nature Communications 10.1 (2019):3785.Google Scholar

Romero, R, Emanuel, K. Climate change and hurricane-like extratropical cyclones: Projections for North Atlantic polar lows and medicanes based on CMIP5 models. Journal of Climate 30.1 (2017):279–299.Google Scholar

Wu, S-Y, Najjar, R, Siewert, J. Potential impacts of sea-level rise on the mid- and upper-Atlantic region of the United States. Climatic Change 95.1–2 (2009):121–138.Google Scholar

Ranco, DJ, O’Neill, CA, Donatuto, J, et al. Environmental justice, American Indians and the cultural dilemma: Developing environmental management for tribal health and well-being. Environmental Justice 4.4 (2011):221–230.Google Scholar

Preston, CJ. Challenges and opportunities for understanding non-economic loss and damage. Ethics, Policy & Environment 20.2 (2017):143–155.Google Scholar

Serdeczny, OM, Bauer, S, Huq, S. Non-economic losses from climate change: Opportunities for policy-oriented research. Climate and Development 10.2 (2018):97–101.Google Scholar

Whyte, K. Settler colonialism, ecology, and environmental injustice. Environment and Society 9.1 (2018):125–144.Google Scholar

Whyte, KP. Justice forward: Tribes, climate adaptation and responsibility. In Maldonado, JK, Colombi, B, Pandya, R, eds. Climate Change and Indigenous Peoples in the United States: Impacts, Experiences and Actions. Springer International Publishing, 2014 [cited November 3, 2021] pp. 9–22. Available from: https://doi.org/10.1007/978-3-319-05266-3_2Google Scholar

Whyte, K. Too late for indigenous climate justice: Ecological and relational tipping points. WIREs Climate Change 11.1 (2020):e603.Google Scholar

Whyte, KP, Brewer, JP, Johnson, JT. Weaving Indigenous science, protocols and sustainability science. Sustainability Science 11.1 (2016):25–32.Google Scholar

Weems, CF, Watts, SE, Marsee, MA, et al. The psychosocial impact of Hurricane Katrina: Contextual differences in psychological symptoms, social support, and discrimination. Behaviour Research and Therapy 45.10 (2007):2295–2306.Google Scholar

Espinel, Z, Galea, S, Kossin, JP, et al. Climate-driven Atlantic hurricanes pose rising threats for psychopathology. The Lancet Psychiatry 6.9 (2019):721–723.Google Scholar

Espinel, Z, Kossin, JP, Galea, S, et al. Forecast: Increasing mental health consequences from Atlantic Hurricanes throughout the 21st century. Psychiatric Services 70.12 (2019):1165–1167.Google Scholar

Shultz, JM, Kossin, JP, Shepherd, JM, et al. Risks, health consequences, and response challenges for small-island-based populations: Observations from the 2017 Atlantic hurricane season. Disaster Medicine and Public Health Preparedness 13.1 (2019):5–17.Google Scholar

IDB (Inter-American Development Bank). Assessment of the Effects and Impacts of Hurricane Dorian in The Bahamas. Inter-American Development Bank, 2020, p. 219.Google Scholar

Knowles, R. Haitian migrants, devastated by Dorian, face deportation from Bahamas. The New York Times, October 10, 2019 [cited August 21, 2020]. Available from: www.nytimes.com/2019/10/10/world/americas/haiti-bahamas-dorian-deport.htmlGoogle Scholar

Smith, D. “The poor are punished”: Dorian lays bare inequality in The Bahamas. The Guardian, September 14, 2019 [cited December 30, 2019]. Available from: www.theguardian.com/world/2019/sep/13/hurricane-dorian-the-mudd-haitians-inequalityGoogle Scholar

USAID (US Agency for International Development). The Bahamas: Hurricane Dorian fact sheet #10. US Agency for International Development, 2019 [cited September 2, 2020] p. 11. Available from: www.usaid.gov/crisis/dorian/fy19/fs10Google Scholar

Shultz, JM, Sands, DE, Kossin, JP, et al. Double environmental injustice: Climate change, Hurricane Dorian, and The Bahamas. New England Journal of Medicine 382.1 (2020):1–3.Google Scholar

WHO (World Health Organization). Quantitative risk assessment of the effects of climate change on selected causes of death, 2030s and 2050s. World Health Organization, 2014 [cited August 20, 2019]. Available from: https://apps.who.int/iris/handle/10665/134014Google Scholar

Vicedo-Cabrera, AM, Scovronick, N, Sera, F, et al. The burden of heat-related mortality attributable to recent human-induced climate change. Nature Climate Change 11.6 (2021):492–500.Google Scholar

Ebi, K, Ogden, NH, Semenza, JC, et al. Detecting and attributing health burdens to climate change. Environmental Health Perspectives 125.8 (2017):085004.Google Scholar

Zhao, Q, Guo, Y, Ye, T, et al. Global, regional, and national burden of mortality associated with non-optimal ambient temperatures from 2000 to 2019: A three-stage modelling study. The Lancet Planetary Health 5.7 (2021):e415–e425.Google Scholar

Tschakert, P, Ellis, NR, Anderson, C, et al. One thousand ways to experience loss: A systematic analysis of climate-related intangible harm from around the world. Global Environmental Change 55 (2019):58–72.Google Scholar

Dückers, MLA, Witteveen, AB, Bisson, JI, et al. The association between disaster vulnerability and post-disaster psychosocial service delivery across Europe. Administration and Policy in Mental Health and Mental Health Services Research 44.4 (2017):470–479.Google Scholar

World Bank. Natural Hazards, Unnatural Disasters: The Economics of Effective Prevention. World Bank, 2010.Google Scholar

Maher, BA, Ahmed, IAM, Karloukovski, V, et al. Magnetite pollution nanoparticles in the human brain. PNAS 113.39 (2016):10797–10801.Google Scholar

van der Geest, K, Warner, K. Loss and damage in the IPCC Fifth Assessment Report (Working Group II): A text-mining analysis. Climate Policy 20.6 (2020):729–742.Google Scholar

Smith, A, Lott, N, Houston, T, et al. U.S. Billion-Dollar Weather and Climate Disasters 1980–2018. National Oceanic and Atmospheric Administration, 2018, pp. 1–14.Google Scholar

UNFCCC (United Nations Framework Convention on Climate Change). Non-economic losses in the context of the work programme on loss and damage. United Nations Framework Convention on Climate Change, 2013 [cited October 29, 2020] p. 65. Available from: https://unfccc.int/resource/docs/2013/tp/02.pdfGoogle Scholar

Tierney, K, Oliver-Smith, A. Social dimensions of disaster recovery. International Journal of Mass Emergencies & Disasters 30.2 (2012).Google Scholar

Tschakert, P. Views from the vulnerable: Understanding climatic and other stressors in the Sahel. Global Environmental Change 17.3–4 (2007):381–396.Google Scholar

Smith, A, Matthews, JL. Quantifying uncertainty and variable sensitivity within the US billion-dollar weather and climate disaster cost estimates. Natural Hazards 77.3 (2015):1829–1851.Google Scholar

Amin, R, Nelson, A, McDougall, S. A spatial study of the location of superfund sites and associated cancer risk. Statistics and Public Policy 5.1 (2018):1–9.Google Scholar

Currie, J, Greenstone, M, Moretti, E. Superfund cleanups and infant health. American Economic Review 101.3 (2011):435–441.Google Scholar

Kramar, DE, Anderson, A, Hilfer, H, et al. A spatially informed analysis of environmental justice: Analyzing the effects of gerrymandering and the proximity of minority populations to U.S. superfund sites. Environmental Justice 11.1 (2018):29–39.Google Scholar

US EPA (Environmental Protection Agency). The role of cost in the superfund remedy selection process. US Environmental Protection Agency, 1996 [cited August 20, 2019]. Available from: https://semspub.epa.gov/work/HQ/174446.pdfGoogle Scholar

US EPA (Environmental Protection Agency). Superfund. US Environmental Protection Agency, 2014 [cited January 28, 2019]. Available from: www.epa.gov/superfundGoogle Scholar

Bowers, ME, Yehuda, R. Intergenerational transmission of stress in humans. Neuropsychopharmacology 41.1 (2016):232–244.Google Scholar

Yehuda, R. Disease markers: Molecular biology of PTSD. Disease Markers 30.2–3 (2011):61–65.Google Scholar

Yehuda, R, Bierer, LM. Transgenerational transmission of cortisol and PTSD risk. De Kloet, ER, Oitzl, MS, Vermetten, E, eds. Progress in Brain Research 167 (2007):121–135.Google Scholar

Marcantonio, R, Fuentes, A. A clear past and a murky future: Life in the Anthropocene on the Pampana River, Sierra Leone. Land 9.3 (2020):72. Available from: https://doi.org/10.3390/land9030072Google Scholar

Farmer, P, Gutierrez, G. In the Company of the Poor. Griffin, M, Block, JW, eds. Orbis Books, 2013.Google Scholar

Martinez-Alier, J. The environmentalism of the poor. Geoforum 54 (2014):239–241.Google Scholar

Martínez-Alier, J. The Environmentalism of the Poor: A Study of Ecological Conflicts and Valuation. Edward Elgar Publishing, 2003.Google Scholar

Beelen, R, Raaschou-Nielsen, O, Stafoggia, M, et al. Effects of long-term exposure to air pollution on natural-cause mortality: An analysis of 22 European cohorts within the multicentre ESCAPE project. The Lancet 383.9919 (2014):785–795.Google Scholar

Bastin, J-F, Clark, E, Elliott, T, et al. Understanding climate change from a global analysis of city analogues. PLOS ONE 14.7 (2019):e0217592.Google Scholar

Zivin, JG,Shrader, J. Temperature extremes, health, and human capital. The Future of Children 26.1 (2016):31–50.Google Scholar

Wrathall, DJ, Oliver-Smith, A, Fekete, A, et al. Problematising loss and damage. International Journal of Global Warming 8.2 (2015):274–294.Google Scholar

Horney, JA, Casillas, GA, Baker, E, et al. Comparing residential contamination in a Houston environmental justice neighborhood before and after Hurricane Harvey. PLOS ONE 13.2 (2018):e0192660.Google Scholar

Kiaghadi, A, Rifai, HS. Physical, chemical, and microbial quality of floodwaters in Houston following Hurricane Harvey. Environmental Science & Technology 53.9 (2019):4832–4840 [cited April 22, 2019]. Available from: https://doi.org/10.1021/acs.est.9b00792Google Scholar

Mandigo, AC, DiScenza, DJ, Keimowitz, AR, et al. Chemical contamination of soils in the New York City area following Hurricane Sandy. Environmental Geochemistry and Health 38.5 (2016):1115–1124.Google Scholar

Sen, A. Poverty and Famines: An Essay on Entitlement and Deprivation. Oxford University Press, 1982.Google Scholar

Gráda, CÓ, O’Rourke, KH. Migration as disaster relief: Lessons from the Great Irish Famine. European Review of Economic History 1.1 (1997):3–25.Google Scholar

Barnett, J. Environmental security. In Castree, N, Hulme, M, Proctor, JD, eds. Companion to Environmental Studies. Routledge, 2018, pp. 188–191.Google Scholar

Verhoeven, H. Gardens of Eden or hearts of darkness? The genealogy of discourses on environmental insecurity and climate wars in Africa. Geopolitics 19.4 (2014):784–805.Google Scholar

Watts, M. Silent Violence: Food, Famine, and Peasantry in Northern Nigeria. University of California Press, 1983.Google Scholar

Butts, KH, Goodman, S, Nugent, N. The concept of environmental security. The Solutions Journal (2016):4.Google Scholar

Bannon, I, Collier, P. Natural Resources and Violent Conflict: Options and Actions. World Bank Publications, 2003.Google Scholar

Burke, M, Hsiang, S, Miguel, E. Climate and conflict. Annual Review of Economics 7.1 (2015):577–617.Google Scholar

Hendrix, CS, Haggard, S. Global food prices, regime type, and urban unrest in the developing world. Journal of Peace Research 52.2 (2015):143–157.Google Scholar

Hsiang, S, Burke, M, Miguel, E. Quantifying the influence of climate on human conflict. Science 341.6151 (2013):1235367–1235367.Google Scholar

Hsiang, S, Burke, M. Climate, conflict, and social stability: What does the evidence say? Climatic Change 123.1 (2014):39–55.Google Scholar

Kelley, CP, Mohtadi, S, Cane, MA, et al. Climate change in the Fertile Crescent and implications of the recent Syrian drought. Proceedings of the National Academy of Sciences 112.11 (2015):3241–3246.Google Scholar

Mach, KJ, Kraan, CM, Adger, N, et al. Climate as a risk factor for armed conflict. Nature 571.7764 (2019):193–197.Google Scholar

Salehyan, I, Hendrix, CS. Climate shocks and political violence. Global Environmental Change 28 (2014):239–250.Google Scholar

Cole, LW, Foster, SR. From the Ground Up: Environmental Racism and the Rise of the Environmental Justice Movement. NYU Press, 2001.Google Scholar

Madrigano, J, Osorio, JC, Bautista, E, et al. Fugitive chemicals and environmental justice: A model for environmental monitoring following climate-related disasters. Environmental Justice 11.3 (2018):95–100.Google Scholar

Martinez-Alier, J, Temper, L, Bene, DD, et al. Is there a global environmental justice movement? The Journal of Peasant Studies 43.3 (2016):731–755.Google Scholar

Bullard, RD. Confronting Environmental Racism: Voices from the Grassroots. South End Press, 1993.Google Scholar

Holifield, R. Defining environmental justice and environmental racism. Urban Geography 22.1 (2001):78–90.Google Scholar

Temper, L, Bene, D del, Martinez-Alier, J. Mapping the frontiers and front lines of global environmental justice: The EJAtlas. Journal of Political Ecology 22.1 (2015):255–278.Google Scholar

Agyeman, J, Schlosberg, D, Craven, L, et al. Trends and directions in environmental justice: From inequity to everyday life, community, and just sustainabilities. Annual Review of Environment and Resources 41.1 (2016):321–340.Google Scholar

Kirsch, S. Mining Capitalism: The Relationship between Corporations and their Critics. University of California Press, 2014.Google Scholar

Vickery, J, Hunter, LM. Native Americans: Where in environmental justice research? Society & Natural Resources 29.1 (2016):36–52.Google Scholar

Allen, S, Fanucchi, MV, McCormick, LC, et al. The search for environmental justice: The story of north Birmingham. International Journal of Environmental Research and Public Health 16.12 (2019):2117.Google Scholar

Vega, CMV, Brown, P, Murphy, C, et al. Community engagement and research translation in Puerto Rico’s Northern Karst Region: The PROTECT Superfund Research Program. New Solution 26.3 (2016):475–495.Google Scholar

Hall, R, Edelman, M, Borras Jr, SM, et al. Resistance, acquiescence or incorporation? An introduction to land grabbing and political reactions “from below.” The Journal of Peasant Studies 42.3–4 (2015):467–488.Google Scholar

Jamal, T, Hales, R. Performative justice: New directions in environmental and social justice. Geoforum 76 (2016):176–180.Google Scholar

Temper, L, Del Bene, D. Transforming knowledge creation for environmental and epistemic justice. Current Opinion in Environmental Sustainability 20 (2016):41–49.Google Scholar

Armiero, M, D’Alisa, G. Rights of resistance: The garbage struggles for environmental justice in Campania, Italy. Capitalism Nature Socialism 23.4 (2012):52–68.Google Scholar

Kojola, E, Pellow, DN. New directions in environmental justice studies: Examining the state and violence. Environmental Politics 30.1–2 (2021):100–118.Google Scholar

Chakrabarty, D. The politics of climate change is more than the politics of capitalism. Theory, Culture & Society 34.2–3 (2017):25–37.Google Scholar

Petryna, A. Life Exposed: Biological Citizens after Chernobyl. Princeton University Press, 2013.Google Scholar

Mishra, P, Samarth, R, Pathak, N, et al. Bhopal gas tragedy: Review of clinical and experimental findings after 25 years. International Journal of Occupational Medicine and Environmental Health 22.3 (2009):193–202.Google Scholar

Manuel, J. Crisis and emergency risk communication: Lessons from the Elk River spill. Environmental Health Perspectives 122.8 (2014):A214–A219.Google Scholar

Murray, CJL, Lopez, AD. Measuring the global burden of disease. New England Journal of Medicine 369.5 (2013):448–457.Google Scholar

Diffenbaugh, NS, Burke, M. Global warming has increased global economic inequality. Proceedings of the National Academy of Sciences of the United States of America 116.20 (2019):9808–9813.Google Scholar

Moe, SJ, Schamphelaere, KD, Clements, WH, et al. Combined and interactive effects of global climate change and toxicants on populations and communities. Environmental Toxicology and Chemistry 32.1 (2013):49–61.Google Scholar

Teron, L, Louis-Charles, HM, Nibbs, F, et al. Establishing a toxics mobility inventory for climate change and pollution. Sustainability 12.4 (2019):226–234.Google Scholar

Hendrix, CS, Salehyan, I. Climate change, rainfall, and social conflict in Africa. Journal of Peace Research 49.1 (2012):35–50.Google Scholar

Hendrix, CS, Glaser, SM. Trends and triggers: Climate, climate change and civil conflict in Sub-Saharan Africa. Political Geography 26.6 (2007):695–715.Google Scholar

Ide, T. Why do conflicts over scarce renewable resources turn violent? A qualitative comparative analysis. Global Environmental Change 33 (2015):61–70.Google Scholar

Collier, P, Hoeffler, A. Resource rents, governance, and conflict. Journal of Conflict Resolution 49.4 (2005):625–633.Google Scholar

Fairhead, J. International dimensions of conflict over natural and environmental resources. In Peluso, NL, Watts, M, eds. Violent Environments. Cornell University Press, 2001, pp. 213–236.Google Scholar

Gemenne, F, Barnett, J, Adger, N, et al. Climate and security: Evidence, emerging risks, and a new agenda. Climatic Change 123.1 (2014):1–9.Google Scholar

Månsson, A. A resource curse for renewables? Conflict and cooperation in the renewable energy sector. Energy Research & Social Science 10 (2015):1–9.Google Scholar

Mildner, S-A, Lauster, G, Wodni, W. Scarcity and abundance revisited: A literature review on natural resources and conflict. International Journal of Conflict and Violence (IJCV) 5.1 (2011):155–172.Google Scholar

Papyrakis, E. The resource curse – what have we learned from two decades of intensive research: Introduction to the special issue. The Journal of Development Studies 53.2 (2017):175–185.Google Scholar

Welsch, H. Resource abundance and internal armed conflict: Types of natural resources and the incidence of “new wars.” Ecological Economics 67.3 (2008):503–513.Google Scholar

Böhmelt, T, Bernauer, T, Buhaug, H, et al. Demand, supply, and restraint: Determinants of domestic water conflict and cooperation. Global Environmental Change 29 (2014):337–348.Google Scholar

Dabelko, D, Aaron, T. Water, conflict, and cooperation. Environmental Change and Security Project Report 10 (2004):60–66.Google Scholar

Gizelis, T-I, Wooden, AE. Water resources, institutions, and intrastate conflict. Political Geography 29.8 (2010):444–453.Google Scholar

Ide, T. Space, discourse and environmental peacebuilding. Third World Quarterly 38.3 (2017):544–562.Google Scholar

Ide, T. Does environmental peacemaking between states work? Insights on cooperative environmental agreements and reconciliation in international rivalries. Journal of Peace Research 55.3 (2018):351–365.Google Scholar

O’Loughlin, J, Linke, AM, Witmer, FDW. Modeling and data choices sway conclusions about climate–conflict links. PNAS 111.6 (2014):2054–2055.Google Scholar

Abel, GJ, Brottrager, M, Crespo Cuaresma, J, et al. Climate, conflict and forced migration. Global Environmental Change 54 (2019):239–249.Google Scholar

Hsiang, S, Meng, KC, Cane, MA. Civil conflicts are associated with the global climate. Nature 476.7361 (2011):438–441.Google Scholar

Levy, BS, Sidel, VW, Patz, JA. Climate change and collective violence. Annual Review of Public Health 38.1 (2017):241–257.Google Scholar

Van Lange, PAM, Rinderu, MI, Bushman, BJ. Aggression and violence around the world: A model of Climate, Aggression, and Self-control in Humans (CLASH). Behavioral and Brain Sciences 40 (2017):e75 [cited June 7, 2018]. Available from: www.cambridge.org/core/product/identifier/S0140525X16000406/type/journal_articleGoogle Scholar

US EPA (Environmental Protection Agency). Types of nonpoint source pollution. US Environmental Protection Agency, 2015 [cited August 30, 2019]. Available from: www.epa.gov/nps/types-nonpoint-source-pollutionGoogle Scholar

US EPA (Environmental Protection Agency). Basic information about nonpoint source (NPS) pollution. US Environmental Protection Agency, 2015 [cited August 30, 2019]. Available from: www.epa.gov/nps/basic-information-about-nonpoint-source-nps-pollutionGoogle Scholar

NOAA (National Oceanic and Atmospheric Administration). NOAA’s national ocean service education: Point and nonpoint source pollution. National Oceanic and Atmospheric Administration, 2017 [cited August 30, 2019]. Available from: https://oceanservice.noaa.gov/education/tutorial_pollution/04nonpointsource.htmlGoogle Scholar

NOAA (National Oceanic and Atmospheric Administration). NOAA’s national ocean service education: Point source pollution. National Oceanic and Atmospheric Administration, 2017 [cited August 30, 2019]. Available from: https://oceanservice.noaa.gov/education/tutorial_pollution/03pointsource.htmlGoogle Scholar

Carson, R. Silent Spring. Houghton Mifflin Harcourt, 1962.Google Scholar

HEF (Health Effects Institute). State of global air 2018: Special report. Health Effects Institute, 2018 [cited October 29, 2018] pp. 1–24. Available from: www.stateofglobalair.org/sites/default/files/soga-2018-report.pdfGoogle Scholar

O’Leary, R, Durant, RF, Fiorino, DJ, et al. Managing for the Environment: Understanding the Legal, Organizational, and Policy Challenges. 1st ed. Jossey-Bass, 1999.Google Scholar

Rodhe, H. A comparison of the contribution of various gases to the greenhouse effect. Science 248.4960 (1990):1217–1219.Google Scholar

Grieshop, AP, Jain, G, Sethuraman, K, et al. Emission factors of health- and climate-relevant pollutants measured in home during a carbon-finance-approved cookstove intervention in rural India. GeoHealth 1.5 (2017):222–236.Google Scholar

Grote, M, Williams, I, Preston, J, et al. Including congestion effects in urban road traffic CO₂ emissions modelling: Do local government authorities have the right options? Transportation Research Part D: Transport and Environment 43 (2016):95–106.Google Scholar

US EPA (Environmental Protection Agency). Summary of the Clean Water Act. US Environmental Protection Agency, 2013 [cited September 4, 2019]. Available from: www.epa.gov/laws-regulations/summary-clean-water-actGoogle Scholar

US EPA (Environmental Protection Agency). Overview of the Clean Air Act and air pollution. US Environmental Protection Agency, 2015 [cited September 4, 2019]. Available from: www.epa.gov/clean-air-act-overviewGoogle Scholar

US EPA (Environmental Protection Agency). Resource Conservation and Recovery Act (RCRA) laws and regulations. US Environmental Protection Agency, 2015 [cited September 4, 2019]. Available from: www.epa.gov/rcraGoogle Scholar

UNFCCC (United Nations Framework Convention on Climate Change). The Paris Climate Agreement. UN Framework Convention on Climate Change, 2015 [cited September 4, 2019] p. 27. Available from: https://unfccc.int/sites/default/files/english_paris_agreement.pdfGoogle Scholar

UNDP (United Nations Development Programme). Montreal Protocol. UNDP, 1987 [cited September 4, 2019]. Available from: https://unep.org/ozonaction/who-we-are/about-montreal-protocolwueGoogle Scholar

Wuebbles, D. Ozone depletion. In Encyclopedia Britannica. Encyclopedia Britannica, Inc., 2018. Available from: www.britannica.com/science/ozone-depletionGoogle Scholar

Petter, PMH, Veit, HM, Bernardes, AM. Evaluation of gold and silver leaching from printed circuit board of cellphones. Waste Management 34.2 (2014):475–482.Google Scholar

US EPA (Environmental Protection Agency). Municipal solid waste generation, recycling, and disposal in the United States: Facts and figures for 2012. US Environmental Protection Agency, 2012 [cited October 14, 2019]. Available from: www.epa.gov/sites/production/files/2015-09/documents/2012_msw_fs.pdfGoogle Scholar

Ferreira, H, Leite, MGP. A life cycle assessment study of iron ore mining. Journal of Cleaner Production 108 (2015):1081–1091.Google Scholar

Seibert, MK, Rees, WE. Through the eye of a needle: An eco-heterodox perspective on the renewable energy transition. Energies 14.15 (2021):4508.Google Scholar

Notter, DA, Gauch, M, Widmer, R, et al. Contribution of li-ion batteries to the environmental impact of electric vehicles. Environmental Science & Technology 44.17 (2010):6550–6556.Google Scholar

Majeau-Bettez, G, Hawkins, TR, Strømman, AH. Life cycle environmental assessment of lithium-ion and nickel metal hydride batteries for plug-in hybrid and battery electric vehicles. Environmental Science & Technology 45.10 (2011):4548–4554.Google Scholar

Bazilian, MD. The mineral foundation of the energy transition. The Extractive Industries and Society 5.1 (2018):93–97.Google Scholar

Bergius, M, Benjaminsen, TA, Maganga, F, et al. Green economy, degradation narratives, and land-use conflicts in Tanzania. World Development 129 (2020):104850.Google Scholar

Büscher, B, Fletcher, R. Under pressure: Conceptualising political ecologies of green wars. Conservation and Society 16.2 (2018):105–113.Google Scholar

Montefrio, MJF. The green economy and land conflict. Peace Review 25.4 (2013):502–509.Google Scholar

Hickel, J. Degrowth: A theory of radical abundance. Real-World Economics Review 87 (2019):262.Google Scholar

WGC (World Gold Council). How much gold has been mined? World Gold Council, 2020 [cited January 17, 2020] p. 27. Available from: www.gold.org/about-gold/gold-supply/gold-mining/how-much-goldGoogle Scholar

UNDP, UNEP (United Nations Development Programme, United Nations Environmental Programme). Managing Mining for Sustainable Development. UN Development Programme and the UN Environmental Programme, 2018, p. 116.Google Scholar

US EIA (Energy Information Administration). How much gasoline does the United States consume? US Energy Information Administration, 2019 [cited October 14, 2019]. Available from: www.eia.gov/tools/faqs/faq.php?id=23&t=10Google Scholar

AFDC. Alternative Fuels Data Center: Fuel properties comparison. US Department of Energy, 2014 [cited October 15, 2019] p. 4. Available from: afdc.energy.gov/fuels/fuel_comparison_chart.pdfGoogle Scholar

Frey, HC. Trends in onroad transportation energy and emissions. Journal of the Air & Waste Management Association 68.6 (2018):514–563.Google Scholar

USDA (US Department of Agriculture). Food waste FAQs. US Department of Agriculture, 2019 [cited October 15, 2019] p. 2. Available from: www.usda.gov/foodwaste/faqsGoogle Scholar

UN FAO (United Nations Food and Agriculture Organization). Key facts on food loss and waste you should know! UN Food and Agriculture Organization, 2019 [cited October 15, 2019] p. 3. Available from: https://twosides.info/includes/files/upload/files/UK/Myths_and_Facts_2016_Sources/18-19/Key_facts_on_food_loss_and_waste_you_should_know-FAO_2016.pdfGoogle Scholar

Sundin, N, Rosell, M, Eriksson, M, et al. The climate impact of excess food intake: An avoidable environmental burden. Resources, Conservation and Recycling 174 (2021):105777.Google Scholar

Toti, E, Di Mattia, C, Serafini, M. Metabolic food waste and ecological impact of obesity in FAO world’s region. Frontiers in Nutrition 6 (2019):126.Google Scholar

Serafini, M, Toti, E. Unsustainability of obesity: Metabolic food waste. Frontiers in Nutrition 3 (2016):40.Google Scholar

LLNL (Lawrence Livermore National Laboratory). Estimated U.S. Energy Consumption in 2019: 100.2 Quads. US Department of Energy, 2020, p. 1.Google Scholar

LLNL (Lawrence Livermore National Laboratory). World Energy Flow. US Department of Energy Lawrence Livermore National Laboratory, 2012, p. 1.Google Scholar

GAHP (Global Alliance on Health and Pollution). Global Pollution Map and Database. Global Alliance on Health and Pollution, 2019, p. 1.Google Scholar

US EPA (Environmental Protection Agency). Smog, soot, and other air pollution from transportation. US Environmental Protection Agency, 2015 [cited October 15, 2019] p. 3. Available from: www.epa.gov/transportation-air-pollution-and-climate-change/smog-soot-and-local-air-pollutionGoogle Scholar

Little, P, Wiffen, RD. Emission and deposition of petrol engine exhaust Pb – I. Deposition of exhaust pb to plant and soil surfaces. Atmospheric Environment (1967) 11.5 (1977):437–447.Google Scholar

Ozaki, H, Watanabe, I, Kuno, K. Investigation of the heavy metal sources in relation to automobiles. Water, Air, & Soil Pollution 157.1 (2004):209–223.Google Scholar

Chen, H, Kwong, JC, Copes, R, et al. Living near major roads and the incidence of dementia, Parkinson’s disease, and multiple sclerosis: A population-based cohort study. The Lancet 389.10070 (2017):718–726.Google Scholar

Sutherland, RA. Lead in grain size fractions of road-deposited sediment. Environmental Pollution 121.2 (2003):229–237.Google Scholar

UN FAO (United Nations Food and Agriculture Organization). World Food and Agriculture: Statistical Pocketbook 2018. UN Food and Agriculture Organization, 2018.Google Scholar

UN FAO (United Nations Food and Agriculture Organization). More People, More Food, Worse Water? A Global Review of Water Pollution from Agriculture. UN Food and Agriculture Organization and the International Water Management Institute, 2018.Google Scholar

Wantzen, KM, Mol, JH. Soil erosion from agriculture and mining: A threat to tropical stream ecosystems. Agriculture 3 (2013):660–683.Google Scholar

Jobbagyi, EG, Jackson, RB. The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecological Applications 10.2 (2000):15.Google Scholar

St. Clair, SB, Lynch, JP. The opening of Pandora’s Box: Climate change impacts on soil fertility and crop nutrition in developing countries. Plant and Soil 335.1–2 (2010):101–115.Google Scholar

US EPA (Environmental Protection Agency). What is the toxics release inventory? US Environmental Protection Agency, 2013 [cited October 16, 2019] p. 3. Available from: www.epa.gov/toxics-release-inventory-tri-program/what-toxics-release-inventoryGoogle Scholar

US EPA (Environmental Protection Agency). TSCA chemical substance inventory. US Environmental Protection Agency, 2014 [cited October 16, 2019]. Available from: www.epa.gov/tsca-inventoryGoogle Scholar

US EPA (Environmental Protection Agency). Overview of EPA’s brownfields program. US Environmental Protection Agency, 2014 [cited October 16, 2019]. Available from: www.epa.gov/brownfields/overview-epas-brownfields-programGoogle Scholar

Wu, Y-C, Lin, Y-C, Yu, H-L, et al. Association between air pollutants and dementia risk in the elderly. Alzheimers Dement (Amst) 1.2 (2015):220–228.Google Scholar

Calderón-Garcidueñas, L, Engle, R, Mora-Tiscareño, A, et al. Exposure to severe urban air pollution influences cognitive outcomes, brain volume and systemic inflammation in clinically healthy children. Brain and Cognition 77.3 (2011):345–355.Google Scholar

Nelson, A, McDougall, S. A spatial study of the location of superfund sites and associated cancer risk. Statistics and Public Policy 5.1 (2018):1–9.Google Scholar

Amin, R, Nelson, A, McDougall, S. A spatial study of the location of superfund sites and associated cancer risk. Statistics and Public Policy 5.1 (2018):1–9.Google Scholar

Filippelli, GM, Laidlaw, MAS. The elephant in the playground: Confronting lead-contaminated soils as an important source of lead burdens to urban populations. Perspectives in Biology and Medicine 53.1 (2010):31–45.Google Scholar

Stone, KW, Casillas, GA, Karaye, I, et al. Using spatial analysis to examine potential sources of polycyclic aromatic hydrocarbons in an environmental justice community after Hurricane Harvey. Environmental Justice 12.4 (2019):194–203.Google Scholar

Marcantonio, R, Field, SP, Sesay, PB, et al. Identifying human health risks from precious metal mining in Sierra Leone. Regional Environmental Change 21.1 (2021):2.Google Scholar

Dethier, EN, Sartain, SL, Lutz, DA. Heightened levels and seasonal inversion of riverine suspended sediment in a tropical biodiversity hot spot due to artisanal gold mining. PNAS 116.48 (2019):23936–23941.Google Scholar

Hauer, ME, Evans, JM, Mishra, DR. Millions projected to be at risk from sea-level rise in the continental United States. Nature Climate Change 6.7 (2016):691–695.Google Scholar

Wetzel, FT, Kissling, WD, Beissmann, H, et al. Future climate change driven sea-level rise: Secondary consequences from human displacement for island biodiversity. Global Change Biology 18.9 (2012):2707–2719.Google Scholar

Dursun, A, Yurdakok, K, Yalcin, SS, et al. Maternal risk factors associated with lead, mercury and cadmium levels in umbilical cord blood, breast milk and newborn hair. The Journal of Maternal-Fetal & Neonatal Medicine 29.6 (2016):954–961.Google Scholar

Klein, LD, Breakey, AA, Scelza, B, et al. Concentrations of trace elements in human milk: Comparisons among women in Argentina, Namibia, Poland, and the United States. PLOS ONE 12.8 (2017):e0183367.Google Scholar

WHO (World Health Organization). Infant and young child feeding. World Health Organization, 2020 [cited January 18, 2021] p. 2. Available from: www.who.int/news-room/fact-sheets/detail/infant-and-young-child-feedingGoogle Scholar

US CDC (Centers for Disease Control and Prevention). Meeting of the Lead Poisoning Prevention Subcommittee of the NCEH/ATSDR Board of Scientific Counselors. US Department of Health and Human Services, Centers for Disease Control and Prevention, 2017, p. 30.Google Scholar

IHME (Institute for Health Metrics and Evaluation). The Global Burden of Disease. Institute for Health Metrics and Evaluation, 2017, p. 3.Google Scholar

UN (United Nations). World Urbanization Prospects: The 2018 Revision. United Nations, Department of Economic and Social Affairs, Population Division, 2019.Google Scholar

UN (United Nations). UN Ocean Conference: People and Oceans Fact Sheet. United Nations, 2017, p. 7.Google Scholar

EPI (Environmental Performance Index). Environmental Performance Index 2018. Yale Center for Environmental Law and Policy, 2018, p. 200.Google Scholar

ND-GAIN (Notre Dame Global Adaptation Index). ND-GAIN Country Index rankings. Notre Dame Global Adaptation Index, 2019 [cited January 12, 2017]. Available from: https://gain.nd.edu/our-work/country-index/Google Scholar

Stephens, L, Fuller, D, Boivin, et al. Archaeological assessment reveals Earth’s early transformation through land use. Science 365.6456 (2019):897–902.Google Scholar

Ellis, EC, Gauthier, N, Goldewijk, KK, et al. People have shaped most of terrestrial nature for at least 12,000 years. PNAS 118.17 (2021):e2023483118 [cited April 26, 2021]. Available from: www.pnas.org/content/118/17/e2023483118Google Scholar

Perez-Padilla, R, Schilmann, A, Riojas-Rodriguez, H. Respiratory health effects of indoor air pollution [review article]. The International Journal of Tuberculosis and Lung Disease 14.9 (2010):1079–1086 [cited October 18, 2019]. Available from: www.ingentaconnect.com/content/iuatld/ijtld/2010/00000014/00000009/art00003Google Scholar