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The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene

Published online by Cambridge University Press:  10 August 2023

John W. Day Open the ORCID record for John W. Day [Opens in a new window] ,
Charles A. Hall ,
Kent Klitgaard ,
Joel D. Gunn ,
Jae-Young Ko  and
Joseph R. Burger
John W. Day*
Affiliation:
Department of Oceanography and Coastal Sciences, Louisiana State University, Baton Rouge, LA, USA
Charles A. Hall
Affiliation:
College of Environmental Science and Forestry, State University of New York, Syracuse, NY, USA
Kent Klitgaard
Affiliation:
Department of Economics, Wells College, Aurora, NY, USA
Joel D. Gunn
Affiliation:
Department of Anthropology, University of North Carolina-Greenboro, Greensboro, NC, USA
Jae-Young Ko
Affiliation:
Department of Public Policy and Administration, Jackson State University, Jackson, MS, USA and Department of Biology, University of Kentucky, Lexington, KY, USA
Joseph R. Burger
Affiliation:
Department of Public Policy and Administration, Jackson State University, Jackson, MS, USA and Department of Biology, University of Kentucky, Lexington, KY, USA
*
Corresponding author: John W. Day; Email: [email protected]
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Abstract

We review impacts of climate change, energy scarcity, and economic frameworks on sustainability of natural and human systems in coastal zones, areas of high biodiversity, productivity, population density, and economic activity. More than 50% of the global population lives within 200 km of a coast, mostly in tropical developing countries. These systems developed during stable Holocene conditions. Changes in global forcings are threatening sustainability of coastal ecosystems and populations. During the Holocene, the earth warmed and became wetter and more productive. Climate changes are impacting coastal systems via sea level rise, stronger tropical cyclones, changes in basin inputs, and extreme weather events. These impacts are passing tipping points as the fossil fuel-powered industrial-technological-agricultural revolution has overwhelmed the source–sink functions of the biosphere and degraded natural systems. The current status of industrialized society is primarily the result of fossil fuel (FF) use. FFs provided more than 80% of global primary energy and are projected to decline to 50% by mid-century. This has profound implications for societal energy requirements, including the transition to a renewable economy. The development of the industrial economy allowed coastal social systems to become spatially separated from their dominant energy and food sources. This will become more difficult to maintain with the fading of cheap energy. It seems inevitable that past growth in energy use, resource consumption, and economic growth cannot be sustained, and coastal areas are in the forefront of these challenges. Rapid planning and cooperation are necessary to minimize impacts of the changes associated with the coming transition. There is an urgent need for a new economic framework to guide society through the transition as mainstream neoclassical economics is not based on natural sciences and does not adequately consider either the importance of energy or the work of nature.

Keywords

climate changebiophysical systemscoastal ecosystemssustainability
Type
Overview Review
Information
Cambridge Prisms: Coastal Futures , Volume 1 , 2023 , e35
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Impact statement

Although coastal zones comprise less than 5% of the earth’s surface, they account for ~50% of the total human population and a large part of the economy. Coastal ecosystems are among the most productive globally, with high values of ecosystem services that exceed $10 trillion annually. The human population is concentrated in tropical coastal areas, which are strongly threatened by 21st-century megatrends. They are at the forefront of climate impacts, which include extreme warming, accelerated sea level rise, increasing frequency of extreme precipitation events and tropical cyclones, and changes in river discharge. Fossil fuels provide more than 80% of the world’s primary energy currently and decrease to 50% by 2050. Transition to a renewable economy will require renewables to grow much more rapidly than fossil fuels did over the 20th century. The development of the modern economic system was underwritten by fossil fuels and the great source–sink functions of the biosphere. However, human activity has depleted the former and overwhelmed the latter. This series of overlapping issues are likely to coalesce in a perfect storm of impacts on humanity as it concentrates in an increasingly impacted and fragile coastal zone. Ironically, more energy will be required to address impacts of climate change and to compensate for and rebuild human and natural infrastructure located there. Coastal systems are provisioned by an energy-intensive global economy where production is often located far from where it is consumed. Transitioning away from fossil fuels, necessitated by depletion and to reduce climate impacts, will itself be energy intensive and will limit other sectors of the economy. All of this is likely to be felt most powerfully in the coastal zone, and society is largely unprepared for dealing with it. There is an urgent need for a new framework to guide society through the coming transition.

Introduction

The world’s coasts are generally areas of high biodiversity, biological productivity, population growth, and economic activity. Since about 2010, the global population has been more than 50% urban (Burger et al., Reference Burger, Brown, Day, Flanagan and Roy2019), and 40% and 50% of the world’s population live within 100 and 200 km, respectively, of an oceanic coast. By comparison, the land area within 100 km of a coast makes up only 9% of the land area of the earth. Some regions are practically all coastal, such as the Malay Archipelago, the West Indies, the Pacific Islands, and most large island countries such as Japan, New Zealand, Madagascar, and the British Isles. Many of the world’s great fisheries are associated with coasts, especially deltas (Pauly and Yanez-Arancibia, Reference Pauly, Yanez-Arancibia, Day, Crump, Kemp and Yanez-Arancibia2013). Deltas comprise a high proportion of the area of coastal ecosystems and about 400 million people live in or adjacent to deltas (Syvitski et al., Reference Syvitski, Anthony, Saito, Zainescu, Day, Bhattacharya and Giosan2022). A majority of the world’s mega-deltas are located in tropical and subtropical coastal zones and most megacities are coastal, including Tokyo, Yangon, Kolkata, Dhaka, Ho Chi Minh City, Shanghai, Cairo, Karachi, Lagos, New York, Los Angeles, Rio de Janeiro, Sao Paulo, and Buenos Aires (Figure 1, Table 1). The globalized trade system is facilitated by large ports such as Shanghai, Rotterdam, Los Angeles-Long Beach, and the lower Mississippi River (Day and Hall, Reference Day and Hall2016). Most growth of population and economic activity in coming decades is projected to occur in coastal areas, especially in the wider tropics (Day et al., Reference Day, Gunn and Burger2021; Kummu et al., Reference Kummu, de Moel, Salvucci, Viviroli, Ward and Varis2022).

Figure 1. The current global distribution of coastal urban areas larger than 100,000 people. Many of the largest cities are in lower income, tropical to subtemperate coastal regions including tropical Africa, South and Southeast Asia, Central America, and the Caribbean (C40.org 2020). The coastal zones enclosed within the dotted lines area are projected to experience multiple climate stresses that will interact with social, political, and economic megatrends that will likely lead to diminished resilience and sustainability (Modified from C40.org 2020 by Day et al., Reference Day, Gunn and Burger2021. Used with permission).

We develop in this paper how a suite of rapidly changing global forcings are coalescing in a “perfect storm” of cascading and interacting events and processes that will impact human society globally but especially humans now living in coastal regions.

Natural and human systems in coastal areas developed during relatively stable environmental conditions of the Holocene. This was especially the case for deltas that require stable sea levels and predictable freshwater and sediment inputs from drainage basins (Giosan et al., Reference Giosan, Syvitski, Constantinescu and Day2014; Day et al., Reference Day, Colten, Kemp, Wolanski, Day, Elliot and Ramachandran2019). However, shifting environmental and socioeconomic baselines such as climate change and energy security are threatening both human and natural systems (e.g., Colten and Day, Reference Colten, Day and Mossop2018; Day et al., Reference Day, Gunn and Burger2021). Changes in a variety of global forcings will severely threaten the sustainability of coastal ecosystems and populations. Central to these forcings is climate change. Over recent decades, climate change impacts have grown dramatically and are passing tipping points, many of which are likely irreversible (Zhang et al., Reference Zhang, Jeong, Yoon, Hy, Wang, Linderholm, Fang, Xiuchen and Deliang2020; Armstrong McKay et al., Reference Armstrong McKay, Staal, Abrams, Winklmann, Sakschewski, Loriani, Fetzer, Cornell, Rockstrom and Lenton2022; Jackson and Jensen, Reference Jackson and Jensen2022; Kemp et al., Reference Kemp, Xu, Depledge, Ebi, Gibbins, Kohler, Rockstrom, Scheffer, Schellnhuber, Steffen and Lenton2022; McGuire, Reference McGuire2022). The global energy system is dominated by FFs (IEA, 2021) that were responsible for the dramatic growth of population and economic activity in the 20th century, particularly in coastal areas. It is also the primary cause of climate change and economic activity that has led to widespread environmental deterioration. The current, growth-centered neoclassical economic framework grew out of western colonialism and coincided with the rapid expansion of population and economy over the past century and a half but is poorly equipped to address global constraints and diminishing resource availability (Hall, Reference Hall2017; Xu et al., Reference Xu, Kohler, Lenton, Jens-Christian and Scheffer2020; Day et al., Reference Day, Gunn and Burger2021). We address these issues in more detail and look to the future of coastal systems in the remainder of the article.

Climate change impacts and coasts

Because of Holocene stability, climate has been hospitable for humans and agriculture for thousands of years. But now climate change is of significantly greater magnitude than during the Holocene and is dramatically impacting the earth system and global society. Coastal zones are at the forefront of areas threatened by climate change in terms of direct impacts due to warming of the atmosphere and oceans, accelerated sea level rise, larger and more intense tropical cyclones, extreme precipitation events, and changes in river discharge and especially given the intense development there. Other climate change forcings impact coastal areas indirectly through drought, water stress, wildfires, and melting polar sea ice, while others are more indirect, for example, drought and decreased precipitation in river basins affect freshwater delivery to coasts (Stott et al., Reference Stott, Stone and Allen2004; Emanuel, Reference Emanuel2005; Webster et al., Reference Webster, Holland, Curry and Chang2005; Hoyos et al., Reference Hoyos, Agudelo, Webster and Cury2006; FitzGerald et al., Reference FitzGerald, Fenster, Argow and Buynevich2008; Pfeffer et al., Reference Pfeffer, Harper and O’Neel2008; Vermeer and Rahmstorf, Reference Vermeer and Rahmstorf2009; Kaufmann et al., Reference Kaufmann, Kauppi, Mann and Stock2011; Min et al., Reference Min, Zhang, Zwiers and Hegerl2011; Pall et al., Reference Pall, Aina, Stone, Stott, Nozawa, Hilberts, Lohmann and Allen2011; Schiermeier, Reference Schiermeier2011; IPCC, 2013; Horton et al., Reference Horton, Rahmstorf, Engelhart and Kemp2014; Mei et al., Reference Mei, Leung, Kwok, Lam and Tang2015; Deconto and Pollard, Reference DeConto and Pollard2016; Kopp et al., Reference Kopp, Kemp, Bittermann, Horton, Donnelly, Gehrels, Hay, Mitrovica, Morrow and Rahmstorf2016; Day et al., Reference Day, Gunn and Burger2021).

Extreme heat is impacting large areas of the globe. Global temperatures have increased by a little more than 1 C since 1880 and are projected to increase by an additional 1.5–2.0 C or more by mid-century, coinciding with a disproportionate increase in the frequency, duration, and geographic extent of heat wave events (IPCC, 2022). For the last 6,000 years, human populations, crops, and livestock occupied a limited thermal window compared to global temperatures (Xu et al., Reference Xu, Kohler, Lenton, Jens-Christian and Scheffer2020). Without a reduction in emissions, this will likely shift even more in the coming decades than was typical of the past 6,000 years. A third of humans may experience mean annual temperatures exceeding 29 C by 2070 in comparison to most living in the nearly optimal 11–15 C range for the past 6,000 years. Especially vulnerable are tropical zones, especially along tropical coasts, because these areas are already in the high end of the temperature range, leading to temperatures exceeding human thermoregulatory capacity. Thirty percent of the world’s population is currently experiencing very high temperature and humidity conditions for part of the year, and that proportion will increase to between 48 and 74% by 2100 (Mora et al., Reference Mora, Dousset, Caldwell, Powell, Geronimo, Bielecki, Counsell, Dietrich, Johnston, Louis and Lucas2017). Increasing mortality from high heat is inevitable, and this is especially true in humid coastal cities where urban ‘heat islands’ exacerbate the problem. Increasing frequency and duration of extreme heat will inevitably require increased energy demand for cooling, leading to inequities in mitigating the effects of climate change (Hughes et al., Reference Hughes, Breshears, Cook, Keith and Burger2023). Increasing heat poses particular challenges for food security in cities globally (Hammond et al., Reference Hammond, Brown, Burger, Flanagan, Fristoe, Mercado-Silva, Nekola and Okie2015) but especially in lower income tropical regions. Marine heat waves have increased in frequency and duration over time (Oliver et al., Reference Oliver, Benthuysen, Darmaraki, Donat, Hobday, Holbrook, Schlegel and Sen Gupta2021), raising the question of ocean heat absorption capacity and increased abrupt die-offs of marine resources (e.g., https://onlinelibrary.wiley.com/doi/10.1111/gcb.16301). In just 16 years (from 2005 to 2021), heat stored by the earth system doubled with possible irreversibly effects to the climate envelope in which humans live (Loeb et al., Reference Loeb, Johnson, Thorsen, Lyman, Rose and Kato2021). As a result, a third of ice in Himalayan glaciers would be lost with 1.5 C warming and 50–65% at higher warming levels (Kraaijenbrink et al., Reference Kraaijenbrink, Bierkens, Lutz and Immerzeel2017).

Oppenheimer et al. (Reference Oppenheimer, Glavovic, Hinkel, van de Wal, Magnan and Abd-Elgawad2019) reported sea level rise estimates and projections of from 1986–2005 to 2081–2,100 (ranges in brackets) (0.43 m (0.29–0.59)-RPC2.6, 0.55 m (0.39–0.72)-RPC4.5, and 0.84 m (0.61–1.10)-RCP 8.5). Especially vulnerable are low-lying coastal regions including tropics and subtropics (see Figure 1) with large deltas and high population densities (Syvitski et al., Reference Syvitski, Kettner, Overeem, Hutton, Hannon, Brakenridge, Day, Vörösmarty, Saito, Giosan and Nicholls2009, Reference Syvitski, Anthony, Saito, Zainescu, Day, Bhattacharya and Giosan2022; Giosan et al., Reference Giosan, Syvitski, Constantinescu and Day2014; Day et al., Reference Day, Agboola, Chen, D’Elia, Forbes, Giosan, Kemp, Kuenzer, Lane, Ramachandran, Syvitski and Yanez-Arancibia2016, Reference Day, Colten, Kemp, Wolanski, Day, Elliot and Ramachandran2019, Reference Day, Gunn and Burger2021). Coastal flooding is projected to be even worse due to climate-induced tidal and storm events (Kirezci et al., Reference Kirezci, Young, Ranasinghe, Muis, Nicholls, Lincke and Hinkel2022) The world’s megacities are primarily in tropical coastal areas (see Table 1). The legacy of anthropogenic impacts to drainage basins of large deltas through localized reclamation, hydrologic alteration, and enhanced subsidence are decreasing the resiliency and sustainability of these areas (Giosan et al., Reference Giosan, Syvitski, Constantinescu and Day2014; Tessler et al., Reference Tessler, Vörösmarty, Grossberg, Gladkova, Aizenman, Syvitski and Foufoula-Georgiou2015; Day et al., Reference Day, Agboola, Chen, D’Elia, Forbes, Giosan, Kemp, Kuenzer, Lane, Ramachandran, Syvitski and Yanez-Arancibia2016, Reference Day, Colten, Kemp, Wolanski, Day, Elliot and Ramachandran2019, Reference Day, Clark, Chang, Hunter and Norman2020).

Table 1. Top 25 largest megacities of the world as of October 2022 (modified from United Nations, 2022)

Note: Country Development Status is from the Human Development Index (https://hdr.undp.org/data-center/human-development-index#/indicies/HDI). Coastal is within 200 km of the ocean.

Warming of ocean surface waters has amplified the frequency and intensity of tropical storms including cyclones and surge events (Emanuel, Reference Emanuel2005; Webster et al., Reference Webster, Holland, Curry and Chang2005; Hoyos et al., Reference Hoyos, Agudelo, Webster and Cury2006; Elsner et al., Reference Elsner, Kossin and Jagger2008; Bender et al., Reference Bender, Knutson, Tuleya, Sirutis, Vecchi, Garner and Held2010; Grinsted et al., Reference Grinsted, Moore and Jevrejeva2012; Mei et al., Reference Mei, Leung, Kwok, Lam and Tang2015; Bhatia et al., Reference Bhatia, Vecchi, Knutson, Murakami, Kossin, Dixon and Whitlock2019). The rate that the strength of hurricanes declines after reaching land has decreased over time (Li and Chakraborty, Reference Li and Chakraborty2020). Countries along the western Pacific and Indian Ocean, which contain many coastal megacities (see Figure 1), are among the most densely populated globally (Burger et al., Reference Burger, Weinberger and Marquet2017, Reference Burger, Brown, Day, Flanagan and Roy2019, Reference Burger, Okie, Hatton, Weinberger, Shrestha, Liedtke, Be, Cruz, Feng, Hinojo-Hinojo and Kibria2022; Burger and Fristoe, Reference Burger and Fristoe2018) and are threatened by tropical cyclones. The impacts are greater in low-income countries that lack the capacity for socioeconomic resiliency to respond to increasing natural disasters (e.g., Dyer, Reference Dyer, Jones and Murphy2009; Tessler et al., Reference Tessler, Vörösmarty, Grossberg, Gladkova, Aizenman, Syvitski and Foufoula-Georgiou2015).

Thus, ongoing climate forcings will affect cities broadly in tropical to subtemperate regions (Figure 1). Because of the multiplicative effects in the lower latitudes, tropical cities will be most vulnerable to cascading effects. Climate change is already impacting the world’s coastal megacities and major deltas (Tessler et al., Reference Tessler, Vörösmarty, Grossberg, Gladkova, Aizenman, Syvitski and Foufoula-Georgiou2015; Day et al., Reference Day, Gunn and Burger2021). The energetic costs and climate impacts of cities in combination with global change forcings raise questions about if urbanization will become more difficult to maintain in the future (Burger et al., Reference Burger, Allen, Brown, Burnside, Davidson and Fristoe2012; Day et al., Reference Day, Gunn and Burger2021; Kummu et al., Reference Kummu, de Moel, Salvucci, Viviroli, Ward and Varis2022). In this review, we address the intersection issues of coastal human–natural systems in the face of global change.

Energy, the renewable transition, and the future of the world’s coasts

A careful consideration of the future trajectory of societal and biophysical systems in coastal regions requires an understanding of the world’s energy system over the past two centuries. The current status of the biosphere and global industrialized society, including coasts, is primarily the result of massive FF use over that time period. This resulted in exponential growth in agricultural production, human populations, and economies, and an overall improvement in the material wellbeing of many humans. This FF growth fueled urbanization and economic growth (Burger et al., Reference Burger, Brown, Day, Flanagan and Roy2019) and the growth of megacities, most of which are coastal (Day et al., Reference Day, Gunn and Burger2021). Unfortunately, it also led to widespread deterioration of many natural systems and dramatic climate impacts. Coastal systems in both their human and biophysical aspects are at the forefront of climate impacts. FFs underwrote practically all growth. This is reflected in the strong statistical relationship between GDP energy consumption patterns (Figure 2; Warr and Ayres, Reference Warr and Ayres2010; Brown et al., Reference Brown, Burnside, Davidson, DeLong, Dunn, Hamilton and Mercado-Silva2011, Reference Brown, Burger, Burnside, Chang, Davidson, Fristoe, Hamilton, Hammond, Kodric-Brown, Mercado-Silva and Nekola2014; Ayres and Voudouris, Reference Ayres and Voudouris2014; Hall, Reference Hall2017; Smil, Reference Smil2022). FF use also allowed much of the global population to live far from the places where most of the resources are produced including energy, food and agricultural products, industrial goods, and services consumed by urban populations (Burger et al., Reference Burger, Allen, Brown, Burnside, Davidson and Fristoe2012). Marine transportation networks powered by FF deliver these goods to their destinations and are a central reason why so many people can and do live in coastal zones.

Figure 2. Growth of world energy production and GDP from 1830 to 2008. “Other” includes solar, wind, and other new renewables (Murphy and Hall, Reference Murphy and Hall2011, used with permission).

Even with rapid growth of renewables, FFs still dominate global primary energy use by humans, providing more than 80% of global primary energy and 75% of energy end use in 2020 (BP, 2021). Thus, FFs are still supporting most economic activity including renewable energy development, and also dealing with the economic impacts of climate change. Fossil fuels are also integral to maintaining human infrastructure and driving discretionary consumption spending. While the development of renewables is growing rapidly, they are largely adding to the total energy available and not substituting for fossil fuels FFs (IEA, 2017). Conventional oil production has reached a peak and is declining now for 38 of 45 oil producing nations and for 6 of 8 continents (Hallock et al., Reference Hallock, Tharakan, Hall, Jefferson and Wu2004; Mushalik, Reference Mushalik2021; Laherrère et al., Reference Laherrère, Hall and Bentley2022).

Both energy use and GDP grew exponentially in the 20th century (Figure 2). By 2011, global energy use was about 500 quadrillion BTU (approximately 500 EJ or 100 billion barrels of oil equivalent; Figure 2). Of this, U.S. demand accounted for nearly one-quarter. According to BP (2021), global primary energy consumption increased 2.7 times from 1970 (204 EJ) to that in 2020 (557 EJ). FFs provided 82% of primary energy in 2020. Oil is the most important FF, followed by coal and natural gas. All other primary energy sources accounted for ~18% in 2020: nuclear, hydropower, and biomass (wood, peat, and dung) were ~ 12–14% and photovoltaics and wind turbines about 4%.

Most projections for future energy use show FFs dominating though mid-century but then declining rapidly (Maggio and Cacciola, Reference Maggio and Cacciola2012; Mohr et al., Reference Mohr, Wang, Ellem, Ward and Giurco2015). The IEA (2021) projects that oil use will level off at about 104 mb/d by the mid-2030s and then decline slowly to 2050. Natural gas will grow to around 4,500 billion m3 in 2030. Global coal demand will grow slightly until 2025 and then decline slowly to 2050. Maggio and Cacciola (Reference Maggio and Cacciola2012) and Mohr et al. (Reference Mohr, Wang, Ellem, Ward and Giurco2015) project that total FF production will peak around 2050 and decline thereafter. These projections are driven by depletion and decreasing net energy of FFs and do not assume replacement by renewables.

Laherrère et al. (Reference Laherrère, Hall and Bentley2022) developed a global assessment of the quantity of oil that remains to be produced, and how much this might limit future global economic development. They first defined different categories of oil and related liquids. They showed that public-domain data for “proved” (1 P) oil reserves, both by-country and globally from the EIA and BP Statistical Review, were extremely suspect. Oil consultancy proved-plus-probable (2P) reserve data are generally backdated to the date of field discovery in attributing a field’s estimated volume and are therefore more reliable (see Laherrère et al., Reference Laherrère, Hall and Bentley2022). They concluded that the amount of remaining oil is probably overstated by 300 Gb in the Middle East and 100 Gb for the Former Soviet Union (FSU). Ultimately, the best statistic to assess how much oil is left to produce in a region is recoverable resource (URR) after production to date is subtracted. Laherrère et al. estimated the global URR for four aggregate classes of oil using Hubbert linearization (HL). Their results ranged from 2,500 Gb for conventional oil to 5,000 Gb for ‘all-liquids’. When oil produced to date is subtracted, estimates of global conventional oil reserves are only about half the EIA estimate. They then estimated the expected dates of maximum resource-limited production globally of the different classes of oil. The time of maximum production ranges from 2019 for conventional oil (the high-quality product that civilization was built on) to about 2040 for ‘all-liquids’. In other words, the world is beginning to see the gradual end of freely available oil. We recognize that “peak oil” has been predicted before, but now it seems to be happening.

Projections of future energy use through the renewable transition

In this section, we report several contrasting views on the resources and needs to move to a renewable world. The contrasts aside, the need to transition is inescapable, and the resources to do so remain limited.

There have been a number of projections of future energy use where renewables are included. Among them is the IEA (2013) that reported FFs provided about 83% of total primary energy in 2011 (Figure 3). Wind and solar were less than 1%. Coal and natural gas were most important for electrical generation with smaller amounts from hydro and nuclear. Residential, industrial, and transport, respectively, represented 32%, 39%, and 28% of energy end use. About 10% of primary energy inputs, mainly oil, were for non-energy uses such as petrochemicals.

Figure 3. World Primary Energy Consumption by Percent Fuel Type from (a) 1980, (b) 2000, (c) 2020 (Source: Modified from BP Statistical Review of World Energy 2021), and (d) projection to 2050. The total energy consumption is 279.4 EJ, 394.5 EJ, 557.1 EJ, and 589.7 EJ for the corresponding years, respectively (Source: calculated from BP Statistical Review of World Energy 2021 for 1980, 2000, 2020, and DNV, Energy Transition Outlook, 2021 for 2050 – estimated).

Four years later, the IEA (2017) reported electricity accounted for only about 18% and 22% of world energy end use in 2011 and 2015, respectively. But in a renewable future, all FFs must be replaced with renewables and nuclear. Replacing present FF-generated electricity by wind and solar using the existing grid is possible but extremely challenging. However, replacing all FF uses with electricity is vastly more difficult and likely impossible because of the greater flexibility of FF energy (Day et al., Reference Day, D’Elia, Wiegman, Rutherford, Hall, Lane and Dismukes2018).

The IPCC (2022) projected energy use for two net-zero CO2 emissions scenarios. By 2045, FFs provide 211 EJ and wind and solar 210 EJ. BP (2021) reported and projected FF for the years 1980, 2000, 2020, and 2050. Their Figure 3 indicates that FFs provided 91%, 86%, and 83% of global primary energy in those years and are projected to supply about 50% by 2050.

At the same time, renewables supplied 0.2%, 0.7%, and 5.7% with a projected 41.1% by 2050. Thus, there has to be an enormous decline in fossil fuels and increase in renewables for this scenario to occur.

For humanity to move toward a sustainable trajectory, an energy transition must occur; however, economic growth requires increasing energy availability, and this will be difficult (e.g., Hall, Reference Hall2017; Day et al., Reference Day, D’Elia, Wiegman, Rutherford, Hall, Lane and Dismukes2018). Whether society can rapidly transition toward a sustainable pathway and meet the demands for provisioning of basic human needs is an open question.

Maggio and Cacciola (Reference Maggio and Cacciola2012) provide rate of growth comparisons that show us how rapidly industrialization was occurring: the number of years it took fossil fuels to grow by an order of magnitude to 2010 levels was total FF 77, oil 64, coal 110, and natural gas 65. By contrast, some projections for the renewable transition are much more rapid. For example, Sgouridis et al. (Reference Sgouridis, Csala and Bardi2016) reported that to replace FFs by 2050, wind and solar would have to grow from <1 Gboe in 2010 (giga barrels of oil equivalent) in 2010 to 102 Gboe by 2050, a factor of 170. By 2019, installed wind and solar represented about 8% of total electricity usage. However, electricity currently represents about 18% of final global end use (Smil, Reference Smil2022), most of which is generated by burning FFs and, by contrast, only about 2% of current total primary energy end use.

Another issue is that if society is to move rapidly energy consumption dominated by FFs to renewables, which generally have a lower energy return on investments (EROIs) to meet climate targets, society would have to allocate substantially more of its GDP to investing in new infrastructure for energy storage, renewable energy sources, and electric power grids. This allocation would reduce EROIs, compete with other economic drivers, and reduce consumption (Hall et al., Reference Hall, Balogh and Murphy2009; Day et al., Reference Day, D’Elia, Wiegman, Rutherford, Hall, Lane and Dismukes2018; Capellan-Perez et al., 2022). Jacobson et al. (2015a, 2015b) estimated that the transition to an entirely renewable energy would require the allocation of 5% of U.S. GDP by 2040. In addition, decommissioning the existing FF infrastructure would require significant quantities of FFs. This would severely limit discretionary investments that facilitate economic growth and reduce EROI (Lambert et al., Reference Lambert, Hall, Balogh, Gupta and Arnold2014; Hall, Reference Hall2017).

Coastal systems are especially vulnerable to changes in the energy system since they are disproportionally impacted by climate change and are areas of high population density and economic growth. The findings of Laherrère et al., Reference Laherrère, Hall and Bentley2022 have profound implications for the renewable transition and are deeply seated in society’s present dependence on FFs. Currently, FFs support more than 80% of the work of society (Figure 3). This includes infrastructure maintenance and consumption as well as investments in obtaining more energy (including the development of renewables). FFs also pay for dealing with damage due to impacts from climate changes and ecosystem degradation, which in turn are mostly caused by FF use.

Economics: The failure of neoclassical and the promise of biophysical economics

How would we plan for, design, or project the ways that humans live and work in a future world where humans are becoming more urbanized and concentrated in increasingly fragile coastal areas? How, especially, could we design such a future that would be more sustainable in a world challenged by what we might consider a “perfect storm” of environmental deterioration, climate change, resource scarcity, and the coming end of the fossil fuel era? We believe that conventional economics is seriously inadequate for addressing the needed changes because it is inconsistent with the basic laws of the natural sciences, is based upon an unrealistic set of assumptions about human behavior and market structure, and does not effectively incorporate any of the new challenges that we identified earlier (see e.g., Hall et al., Reference Hall, Lindenberger, Kümmel, Kroeger and Eichhorn2001; Hall, Reference Hall2017). Although it has gone largely unheeded, there is a long history of critiques of the essentially absurd assumptions of NCE that violate many laws of physics (e.g., Boulding, Reference Boulding1968; Georgescu-Roegen, Reference Georgescu-Roegen1971; Cleveland et al., Reference Cleveland, Costanza, Hall and Kaufmann1984; Hall et al., Reference Hall, Lindenberger, Kümmel, Kroeger and Eichhorn2001; Hall, Reference Hall2017). Herman Daly’s many works on steady-state economics, sustainability, and ecological economics are a scholarly and convincing critique of NCE (Daly, Reference Daly1977, Reference Daly2007; Daly and Cobb, Reference Daly and Cobb1989; Daly and Farley, Reference Daly and Farley2004; Daly, Reference Daly2014). The shortcomings of NCE manifest most profoundly in coastal areas where one of the most dire impacts of modern industrial society, that of climate change, are being felt most strongly.

The neoclassical conception of the rational, maximizing, self-regarding consumer in a world where perfect information is represented in present day prices is incompatible with future sustainability. If the neoclassical premise that human beings are insatiable in their desires for greater happiness, achieved by means of ever-increasing material consumption is correct, the chances of arresting climate change, resource depletion, and the transcendence of even more planetary boundaries are negligible. Yet this behavior is often prominent among the affluent in coastal cities where people flock to the greater incomes and employment, greater array of consumer goods, and higher energy lifestyles of the seacoast.

The world in which we live in is not characterized by the neoclassical vision of atomistic perfectly competitive firms that are unable to control, or even influence, prices; have neither technological advantage nor unique products; and are willing to accept no economic profit in the long term. Yet according to NCE, such an abstract and unrealistic economy is the only one that can produce efficiency and equity in the long run. Rather the actually existing economy is one dominated by large-scale concentrated corporations, or oligopolies, in sectors such as manufacturing, finance, agribusiness, and electronic communication. Highly concentrated corporations can maximize profits in the long run by controlling and externalizing costs and expanding their market shares. But when forms of market power (imperfect competition) are considered, long-run solutions are neither efficient nor equitable. Rather they are characterized by inefficiency, exploitation, periodic depressions, and an unequal distribution of incomes. An oligopolized market structure not only produces the perpetual need to accumulate, as implied in the need to increase market share, but also increased inequality and environmental destruction as a consequence of seeking to control costs.

However, neoclassical economics treats environmental problems of all sorts as external to the main analysis, and if it does think about the environment, it is only by (barely) moving the environmental problems into the market system as “externalities”, subject to cost–benefit analysis to ensure that the cost of remediation or adaptation is not too high for the present generation.

There is a need for a new economic paradigm that is consistent with the constraints imposed by earth systems and yet integrates the limits found in nature with the limits found in the internal dynamics of a globalized concentrated market structure dominated by finance and not the entrepreneurial firm. One alternative approach to economics starts with natural science and heterodox political economy and builds on them.

This integrative framework, which we call biophysical economics, would address these problems by integrating the material and energy needs and possibilities into the initial assumptions and analyses of economic theory. A crucial starting point of biophysical economics is to conceptualize the economy as a flow of materials and energy, and not just a flow of abstract value, or money. While money can theoretically expand forever, materials and energy are limited by the finite nature of earth systems, and biophysical limits to growth are real on a finite planet. As we deplete our earthly sources and fill our sinks with societal effluents, the limits inch closer with every passing day, taking the form of increasing atmospheric carbon dioxide, depletion of crucial resources, including fossil fuels, ocean acidification, and increasing pollution, as we approach and exceed, our planetary boundaries (Rockstrom et al., Reference Rockstrom2009). Many scientific analyses are well aware of these physical and biological phenomena.

What makes biophysical economics unique is the integration of limits to growth found in nature with those found in the internal dynamics of the concentrated economy itself. While in the past, the economy needed to grow to remain viable, strong internal tendencies produce periodic recessions as well as long-term stagnation, or slow growth. This stagnation appears to be increasing, and the average growth rate for the United States during the 1940s was nearly 6% per year, but after domestic oil peaked in the continental United States, growth rates began to fall over time (Hall, Reference Hall2017). The average growth rate during the 2010s was only 1.9%, and the first quarter of 2023 produced a growth rate of only 1.1%. While in the past when the large economic surplus was not consumed or invested, it had to be wasted in endeavors such as advertising or in an energy grid based upon geographically concentrated electricity generation and long-distance transmission. But in the future, neither conspicuous consumption nor copious waste is a viable strategy for a sustainable economy, especially a coastal economy. All the surplus, and probably more, will be absorbed by attempting to maintain increasingly vulnerable infrastructure. Most citizens will see the result as inflation, which will make polities increasingly difficult to govern just as they need good governance.

In short, NCE is no longer up to the task of guiding society and the economy. There is a need for a rapid transition to biophysical economics, which respects the laws of nature and the functioning of the biosphere, and analyzes the economy as it actually exists. A viable theory must address the material and energy requirements, as BPE does, and not simply the growth in terms of money to devise a solution to a society whose growth now pressures our planetary boundaries. Coastal areas are emblematic of these problems because 50% of the world population lives within 200 km of a coast, economic activity is increasingly concentrated in coastal areas, especially tropical ones, and these areas are in the forefront of the impacts of climate change and ecosystem deterioration. Because coastal systems are among the most productive ecosystems on earth, they provide vast ecosystem goods and services to society. Much of the global economy is focused on coastal areas, and most of the world’s trade passes through coastal ports. However, these areas are among the most threatened globally. These factors must be addressed by economic analyses. The framework of biophysical economics encompasses these realities.

Provisioning of coastal social and economic systems

What does it take to support global coastal populations? Certainly, maintaining local coastal populations and infrastructure is critically important because the majority of global population is coastal. But combined global forcings will impact and is already impacting people and the ability to maintain infrastructure. Often resources, especially increasingly expensive energy, that are used to maintain coastal populations are sourced from long distances that are mostly non-coastal and growing global stresses will make this increasingly difficult. Coastal economies in poorer countries have fewer resources to address impacts on infrastructure and flows of energy and materials necessary to maintain coastal populations and economies and are less able to afford costs of dealing with climate change and environmental degradation (Tessler et al., Reference Tessler, Vörösmarty, Grossberg, Gladkova, Aizenman, Syvitski and Foufoula-Georgiou2015; Day et al., Reference Day, Agboola, Chen, D’Elia, Forbes, Giosan, Kemp, Kuenzer, Lane, Ramachandran, Syvitski and Yanez-Arancibia2016, Reference Day, D’Elia, Wiegman, Rutherford, Hall, Lane and Dismukes2018, Reference Day, Gunn and Burger2021).

The global energy system is critical and central to sustaining human populations and economies. The world is moving toward a transition to renewable energy, mainly wind and solar, but total world primary energy sources are still overwhelmingly dominated by fossil fuels. Even though renewable energy growth has been dramatic, new renewables still supply a small percentage of total world energy use. Renewables have not displaced fossil fuel use because of the continued growth in total global energy consumption. LaHerrère et al. (Reference Laherrère, Hall and Bentley2022) showed that total petroleum resources that will ultimately be produced are only half of what was previously thought to be available. Currently, fossil fuels are required for almost all renewable development as well as all other work in society, including the rebuilding of the many coastal regions devastated by hurricanes and flooding. There will be increasing competition for fossil fuels, which underwrites economic activity that supports societal investments (energy acquisition, infrastructure maintenance, pensions and health care, discretionary spending for such things as parks, arts, and museums) and consumption (staples and discretionary spending). High levels of discretionary spending are what characterizes richer societies. An important question is can they be sustained as net energy resources are diminished (e.g., Hall et al., Reference Hall, Powers, Schoenberg and Pimentel2008)?

FFs are sourced from a globally distributed array of coal, and oil and natural gas fields (Figures 4 and 5). FFs have to be extracted from these fields, processed, and shipped to where they will be used. Because the ultimately recoverable petroleum reserves are only about half of what was projected by the IEA, there will be increasing shortages of petroleum in the relatively near future and the net energy yield (EROI) will be less. These increased costs will weigh heavily on the economy, especially in coastal regions in developing countries. This suggests that the renewable transition will be very difficult, if not impossible, if the future economy is expected to look like the present.

Figure 4. Major coal fields of the world (Suárez-Ruiz et al., Reference Suárez-Ruiz, Diez and Rubiera2019). Most are far from coasts. Used with permission.

Figure 5. Major oil and gas fields of the world. Oil endowment (cumulative production plus remaining reserves and undiscovered resources) for provinces assessed (from USGS, 2003). Darker green indicates more resources. Measured regions include (1) the former Soviet Union, (2) the Middle East and North Africa, (3) Asia-Pacific, (4) Europe, (5) North America, (6) Central and South America, (7) sub-Saharan Africa and Antarctica, and (8) South Asia (USGS, 2003). Alaska and the U.S. Gulf coast are not shown here. Red lines indicate the location of the edge of the continental shelf. Used with permission.

Much of the food to feed growing coastal populations is sourced from a globalized food system spread over many parts of the earth. They are generally not near where coastal people live (Figure 6). Fouberg et al. (Reference Fouberg, Murphy and DeBlij2015) list thirteen different food-producing systems. Seven of these are traded to a significant extent in the globalized industrial food system: dairying (1), fruit, truck, and specialized crops (2), mixed livestock and crops (3), commercial grain farming (4), Mediterranean agriculture (6), plantation agriculture, mainly tropical (7), and livestock ranching (12). Six of the food systems are primarily subsistence food production: subsistence crop and livestock farming (5), intensive subsistence farming, chiefly rice (8), intensive subsistence farming, chiefly wheat and other crops (9), rudimentary sedentary cultivation (10), shifting cultivation (11), and nomadic and seminomadic herding (13). This latter group is traded to a lesser extent in the global food system or not at all.

Figure 6. Major food-producing areas of the world. Used with permission.

Producing the food traded in the global food system is highly energy intensive. The average item of food in the United States travels an average of 1,500 miles from where it is produced to where it is consumed. From the farm field to the plate, the global food system requires 15–30% of total primary energy (Marshall and Brockway, Reference Marshall and Brockway2020; Schramski et al., Reference Schramski, Woodson and Brown2020). Country-level food self-sufficiency has declined over the last four decades (Schramski et al., Reference Schramski, Woodson, Steck, Munn and Brown2019), and, as we have shown, many of these countries are in tropical coastal zones. Climate change and environmental degradation are strongly impacting food production (e.g., Xu et al., Reference Xu, Kohler, Lenton, Jens-Christian and Scheffer2020). It is certain that increasing energy prices and resource shortages will severely impact the food system.

Likewise, the globalized trade system that provides the goods and services that maintains human society is widely distributed and consumes enormous quantities of goods and energy and will also be impacted by growing energy scarcity and climate change. The most important exchange points in the global trade system are coastal cities, and these are threatened by several ongoing, climate change processes. For example, the ports of Shanghai, New Orleans and the lower Mississippi River, and Rotterdam are in deltas with large areas below sea level. The former two are in the tropical cyclone belt. The port of Los Angeles is in a region being consumed by drought and fire. The whole world trading system is, of course, underwritten by cheap fossil fuels. Jackson and Jensen (Reference Jackson and Jensen2022) argue that the future will be characterized by fewer people consuming fewer resources. This has dire implications for the globalized industrial society, especially coastal systems that are often far removed from major food production areas (Kummu et al., Reference Kummu, de Moel, Salvucci, Viviroli, Ward and Varis2022).

The world’s coasts: Shifting baselines and diminishing sustainability – Summary and conclusions

In this section, we summarize the environmental baseline under which coastal systems and societies developed during the Holocene and then describe how this baseline has changed and the implications for future sustainability.

Compared to the late Pleistocene, the Holocene climate of the past ten thousand years was relatively stable. Global average temperature was about 5 C warmer than that during the glacial period. This resulted in a wetter climate and significantly higher terrestrial and marine global net primary productivity (NPP). This was especially pronounced over shallow shelfs as rising sea levels flooded the continental margins. Since stabilization about six thousand years ago, sea level has been relatively stable, varying by only a few meters after rising about 130 m. This was the period of Holocene delta building, and coastal margin productivity increased after sea level stabilization (Day et al. Reference Day, Boesch, Clairain, Kemp, Laska, Mitsch, Orth, Mashriqui, Reed, Shabman, Simenstad, Streever, Twilley, Watson, Wells and Whigham2007a, Reference Day, Gunn, Folan, Yanez-Arancibia and Horton2007b, Reference Day, Gunn, Folan, Yanez-Arancibia and Horton2012a, Reference Day, Yanez-Arancibia and Rybczyk2012b). In general, coastal margins experienced much higher levels of freshwater and material inputs from drainage basins. Areas that were covered by ice sheets experienced isostatic rebound. Large deltas grew rapidly after level stabilization but experienced subsidence due to sediment loading, which was offset by deposition of sediments from continental sediment input as well as biogenic substrate formation.

The human population grew slowly from the beginning of the Holocene to about one billion by 1800. Beginning about 12,000 years ago, agriculture spread rapidly and many people settled in small villages. Between 7,000 and 5,000 years ago, the first urban areas appeared, primarily in coastal margins, and often associated with deltas as in Mesopotamia, Pakistan, China, Mesoamerica, and Peru. The massive increase in coastal margin productivity coincided with urbanization that was typified by increasing social complexity and inequality and monumental architecture that included large public works (Day et al., Reference Day, Gunn, Folan, Yanez-Arancibia and Horton2007b, Reference Day, Yanez-Arancibia and Rybczyk2012b; Gunn et al., Reference Gunn, Day, Folan and Moerschbaecher2019). From the beginning of agriculture to the beginning of the industrial revolution in the 18th century, humans lived sustainably from the ecosystem goods and services provided by the biogeosphere. Societies waxed and waned due to factors such as climate variability and ecosystem degradation (Tainter, Reference Tainter1988, Reference Tainter2005; Diamond, Reference Diamond2005; Chew, Reference Chew2007), but overall population increased, and humans spread over the habitable land surface of the earth. Although human activity significantly impacted the earth system locally, it never reached levels that affected global sustainability until the 20th century.

This changed with the advent of the industrial revolution powered by FFs. Industrialization originally was based on water wheels, windmills, and burning wood, all of which can be considered as ecosystem services. Without FFs, the industrial revolution would have quickly become limited by energy scarcity. It was FFs that supported the dramatic exponential growth of energy use, the economy, population, and many other processes in the 20th century. This dramatic growth has been termed the great acceleration and led to a new geologic epoch called the Anthropocene (Steffen et al., Reference Steffen, Richardson, Rockström, Cornell, Fetzer, Bennett, Biggs, Carpenter, De Vries, De Wit and Folke2015; Syvitski et al., Reference Syvitski, Waters, Day, Milliman, Summerhayes, Steffen, Zalasiewicz, Cearreta, Gałuszka, Hajdas and Head2020). Most economic activity and population are now concentrated in coastal areas. Abundant, cheap fossil fuels played a central role in underwriting all these trends. Continuation of this growth seems impossible in a future of ever-increasing resource constraints, climate impacts, population growth, and environmental deterioration. This is particularly true for coastal areas, which are among the social and natural systems most threatened by climate change. Past growth rates were self-limiting and relatively short-lived compared to the long history of earth and humanity.

The industrial revolution has seen both unprecedented human numbers and wealth but also dramatic environmental deterioration and increasingly catastrophic climate change. Both natural and human systems in the coastal zone are affected by climate change and increased subsidence due to fluid withdrawal and reclamation. The finding that the ultimately recoverable petroleum resources are only half of what has been projected, meaning that it is unlikely that there will beadequate energy resources to support the renewable transition, meeting sustainability goals, infrastructure maintenance, and pay for the cost of climate impacts, while providing for much of discretionary spending. Unfortunately, there will likely be sufficient FFs burned to lead to substantial climate impacts in the coastal zone. Further population and economic growth will lead to increased pressure on resources and greater climate impacts and environmental deterioration. It seems inevitable that the great acceleration will slow and reverse, even while human pressure will lead to further exceedance of the carrying capacity of the earth.

Most population growth is currently occurring in developing countries in the tropical zone. The net result of the “exponential” century is that the great source and sink functions of the biosphere have been greatly diminished. Climate change impacts have grown so dramatically that many investigators have concluded that catastrophic climate impacts are irreversible and coastal systems are at the forefront of climate change. Careful planning, cooperation, and likely Draconian legislation will be necessary to minimize the social damage of coming changes and not blind faith in unregulated markets. It seems inevitable that past patterns of energy use, resource consumption, and economic growth cannot be sustained. Neoclassical economics is conceptually and practically unable to deal in a meaningful way with this suite of problems, and a new economic system based on the laws of nature is necessary to guide humanity through the coming transition.

In summary, there are a series of overlapping issues that are likely to coalesce in a perfect storm of impacts on humanity as it gathers increasingly in an increasing impacted and fragile coastal zone. More and more energy will be required to address impacts of climate change and to compensate for and rebuild the human and natural infrastructure located there. Food will be grown at locations far from human populations, probably with increasing use of fossil fuels, while coastal food production will be increasingly stressed. Transitioning away from fossil fuels, necessitated by depletion and to reduce climate impacts, will be energy intensive and may use much of the remaining fossil fuels. Humans are psychologically not prepared for this as the dominant economic systems tell us that the material desires of human choices are what are most important and are infinitely possible to fulfill. All of this is likely to be felt most powerfully in the coastal zone, and society is largely unprepared for dealing with it.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/cft.2023.23.

Data availability statement

No original data were used in this review article.

Acknowledgements

We thank 3 reviewers and Dr. Tom Spencer for thoughtful comments. Jessica Stephens helped with the production and submittal of the paper.

Author contribution

All authors contributed to the conceptualization, writing, and review of the manuscript.

Financial support

This work did not have any direct financial grant support.

Competing interest

The authors declare none.

References

Armstrong McKay, DI, Staal, A, Abrams, J, Winklmann, R, Sakschewski, B, Loriani, S, Fetzer, I, Cornell, SE, Rockstrom, J and Lenton, TM (2022) Exceeding 1.5°C global warming could trigger multiple climate tipping points. Science 377(6611), eabn7950. https://doi.org/10.1126/science.abn7950CrossRefGoogle ScholarPubMed
Ayres, R and Voudouris, V (2014) Energy policy. Biophysical Economics and Resource Quality 64(C), 1628.Google Scholar
Bender, MA, Knutson, TR, Tuleya, RE, Sirutis, JJ, Vecchi, GA, Garner, ST and Held, IM (2010) Modeled impact of anthropogenic warming on the frequency of intense Atlantic hurricanes. Science, 327(5964), 454458. https://doi.org/10.1126/science.1180568CrossRefGoogle ScholarPubMed
Bhatia, KT, Vecchi, GA, Knutson, TR, Murakami, H, Kossin, J, Dixon, KW and Whitlock, CE (2019) Recent increases in tropical cyclone intensification rates. Nature Communications 10(1), 635. https://doi.org/10.1038/s41467-019-08471-zCrossRefGoogle ScholarPubMed
Boulding, KE (1968) Preface to a special issue. Journal of Conflict Resolution 12(4), 409411. https://doi.org/10.1177/002200276801200401CrossRefGoogle Scholar
BP (2021) BP Statistical Review of World Energy 2021 70th Edition. Heriot-Watt University, ceerp.hw.ac.uk: Centre for Energy Economics Research and Policy. Available at https://www.bp.com/content/dam/bp/business-sites/en/global/corporate/pdfs/energy-economics/statistical-review/bp-stats-review-2021-full-report.pdf (accessed April 2023).Google Scholar
Brown, JH, Burger, JR, Burnside, WR, Chang, M, Davidson, AD, Fristoe, TS, Hamilton, MJ, Hammond, ST, Kodric-Brown, A, Mercado-Silva, N and Nekola, JC (2014) Macroecology meets macroeconomics: Resource scarcity and global sustainability. Ecological Engineering 65, 2432. https://doi.org/10.1016/j.ecoleng.2013.07.071CrossRefGoogle ScholarPubMed
Brown, JH, Burnside, WR, Davidson, AD, DeLong, JP, Dunn, WC, Hamilton, MJ, Mercado-Silva, N, et al. (2011) Energetic limits to economic growth. Bioscience 61(1), 1926. https://doi.org/10.1525/bio.2011.61.1.7CrossRefGoogle Scholar
Burger, JR, Allen, CD, Brown, JH, Burnside, WR, Davidson, AD, Fristoe, TS, et al. (2012) The macroecology of sustainability. PLoS Biology 10(6), e1001345. https://doi.org/10.1371/journal.pbio.1001345CrossRefGoogle ScholarPubMed
Burger, JR, Weinberger, VP and Marquet, PA (2017) Extra-metabolic energy use and the rise in human hyper-density. Scientific Reports 7, 15.CrossRefGoogle ScholarPubMed
Burger, JR and Fristoe, TS (2018) Hunter-gatherer populations inform modern ecology. Proceedings of the National Academy of Sciences 115(6), 11371139.CrossRefGoogle ScholarPubMed
Burger, JR, Brown, JH, Day, JW, Flanagan, TP and Roy, ED (2019) The central role of energy in the urban transition: Global challenges for sustainability. BioPhysical Economics and Resource Quality 4, 113.CrossRefGoogle Scholar
Burger, JR, Okie, JG, Hatton, IA, Weinberger, VP, Shrestha, M, Liedtke, KJ, Be, T, Cruz, AR, Feng, X, Hinojo-Hinojo, C and Kibria, AS (2022) Global city densities: Re-examining urban scaling theory. Frontiers in Conservation Science 3(125). https://doi.org/10.3389/fcosc.2022.879934CrossRefGoogle Scholar
Chew, SC (2007) The Recurring Dark Ages: Ecological Stress, Climate Changes, and System Transformation. Lanham, MD: Altimira Press.Google Scholar
Cleveland, CJ, Costanza, R, Hall, CAS and Kaufmann, R (1984) Energy and the United States economy: A biophysical perspective. Science 225, 890897.CrossRefGoogle ScholarPubMed
Colten, CE and Day, JW (2018). Resilience of natural systems and human communities in the Mississippi Delta: Moving beyond adaptability due to shifting baselines. In Mossop, E (ed.), Sustainable Coastal Design and Planning. Boca Raton, FL: CRC Press, pp. 209222.CrossRefGoogle Scholar
Daly, HE (1977) Steady State Economics. San Francisco: W. H. Freeman.Google Scholar
Daly, HE (2007) Ecological Economics and Sustainable Development. Northampton, MA: Edward Elgar Publishing.Google Scholar
Daly, HE and Cobb, JB (1989) For the Common Good: Redirecting the Economy toward Community, the Environment, and a Sustainable Future, 2nd Edn. Boston, MA: Beacon Press.Google Scholar
Daly, HE (2014) Beyond Growth: The Economics of Sustainable Development. Boston: Beacon Press.Google Scholar
Daly, HE and Farley, J (2004) Ecological Economics: Principles and Applications. Washington, DC: Island Press.Google Scholar
Day, JW, Boesch, D, Clairain, E, Kemp, P, Laska, S, Mitsch, W, Orth, K, Mashriqui, H, Reed, D, Shabman, L, Simenstad, C, Streever, B, Twilley, R, Watson, C, Wells, J and Whigham, D (2007a) Restoration of the Mississippi Delta: Lessons from hurricanes Katrina and Rita. Science 315, 16791684.CrossRefGoogle ScholarPubMed
Day, JW, Gunn, J, Folan, W, Yanez-Arancibia, A and Horton, B (2007b) Emergence of complex societies after sea level stabilized. Eos 88, 170171.Google Scholar
Day, JW, Gunn, J, Folan, W, Yanez-Arancibia, A and Horton, B (2012a) The influence of enhanced post-glacial coastal margin productivity on the emergence of complex societies. The Journal of Island and Coastal Archaeology 7, 2352.CrossRefGoogle Scholar
Day, JW, Yanez-Arancibia, A and Rybczyk, JM (2012b) Climate change effects, causes, consequences: Physical, hydromorphological, ecophysiological, and biogeographical changes. Estuarine Treatise 8, 303315.Google Scholar
Day, JW and Hall, CAS (2016) America’s Most Sustainable Cities and Regions: Surviving the 21st Century Megatrends. New York: Springer.CrossRefGoogle Scholar
Day, JW, Agboola, J, Chen, Z, D’Elia, C, Forbes, DL, Giosan, L, Kemp, P, Kuenzer, C, Lane, RR, Ramachandran, R, Syvitski, J and Yanez-Arancibia, A (2016) Approaches to defining deltaic sustainability in the 21st century. Estuarine, Coastal and Shelf Science 183, 275–91. https://doi.org/10.1016/j.ecss.2016.06.018CrossRefGoogle Scholar
Day, JW, D’Elia, CF, Wiegman, AR, Rutherford, JS, Hall, CAS, Lane, RR and Dismukes, DE (2018) The energy pillars of society: Perverse interactions of human resource use, the economy, and environmental degradation. BioPhysical Economics and Resource Quality 3(2), 16. https://doi.org/10.1007/s41247-018-0035-6CrossRefGoogle Scholar
Day, JW, Colten, CE and Kemp, P. (2019). Mississippi Delta restoration and protection: Shifting baselines, diminishing resilience, and growing non-sustainability. In Wolanski, J, Day, JW, Elliot, M and Ramachandran, R (eds.), Coasts and Estuaries - The Future. Amsterdam: Elsevier, pp.173192.Google Scholar
Day, JW, Clark, HC, Chang, C, Hunter, R and Norman, CR (2020) Life cycle of oil and gas fields in the Mississippi River Delta: A review. Water 12(5), 130. https://doi.org/10.3390/w12051492CrossRefGoogle Scholar
Day, JW, Gunn, JD and Burger, JR (2021) Diminishing opportunities for sustainability of coastal cities in the Anthropocene: A review. Frontiers Environmental Science 9, 663275. https://doi.org/10.3389/fenvs.2021.663275CrossRefGoogle Scholar
DeConto, RM and Pollard, D (2016) Contribution of Antarctica to past and future sea-level rise. Nature 531(7596), 591597.CrossRefGoogle ScholarPubMed
Diamond, J (2005) Collapse: How Societies Choose to Fail or Succeed. New York: Viking Adult.Google Scholar
DNV (2021) Energy Transition Outlook 2021. Available at https://eto.dnv.com/2021 (accessed April 2023).Google Scholar
Dyer, CL (2009) From the Phoenix effect to punctuated entropy: The culture of response as a unifying paradigm of disaster mitigation and recovery.” In Jones, E and Murphy, A (eds.), The Political Economy of Hazards and Disasters. Lanham, MD: AltaMira Press, pp. 3133356.Google Scholar
Elsner, JB, Kossin, JP and Jagger, TH (2008) The increasing intensity of the strongest tropical cyclones. Nature 455(7209), 9295. https://doi.org/10.1038/nature07234CrossRefGoogle ScholarPubMed
Emanuel, K (2005) Increasing destructiveness of tropical cyclones over the past 30 years. Nature 436(7051), 686688. https://doi.org/10.1038/nature03906CrossRefGoogle ScholarPubMed
FitzGerald, DM, Fenster, MS, Argow, BA and Buynevich, IV (2008) Coastal impacts due to sea-level rise. Annual Review of Earth and Planetary Sciences 36, 601647.CrossRefGoogle Scholar
Fouberg, E, Murphy, A and DeBlij, H (2015). Human Geography: People, Place and Culture, 11th Edn. Hoboken, NJ: John Wiley & Sons.Google Scholar
Georgescu-Roegen, N (1971) The Entropy Law and the Economic Process. Cambridge, MA: Harvard University Press.CrossRefGoogle Scholar
Giosan, L, Syvitski, J, Constantinescu, S and Day, J (2014) Climate change: Protect the world’s deltas. Nature 516(7529), 3133.CrossRefGoogle ScholarPubMed
Grinsted, A, Moore, JC and Jevrejeva, S (2012) Homogeneous record of Atlantic hurricane surge threat since 1923. Proceedings of the National Academy of Sciences 109(48), 1960119605. https://doi.org/10.1073/pnas.1209542109CrossRefGoogle ScholarPubMed
Gunn, JD, Day, JW, Folan, WJ and Moerschbaecher, M (2019) Geo-cultural time: Advancing human societal complexity within worldwide constraint bottlenecks: A chronological/helical approach to understanding human-planetary interactions. BioPhysical Economics and Resource Quality 4, 119.CrossRefGoogle Scholar
Hall, CAS, Lindenberger, D, Kümmel, R, Kroeger, T and Eichhorn, W (2001) The need to reintegrate the natural sciences with economics. Bioscience 51(8), 663673.CrossRefGoogle Scholar
Hall, CAS (2017) Energy Return on Investment: A Unifying Principle for Biology, Economics and Sustainability. New York: Springer Nature.CrossRefGoogle Scholar
Hall, CAS, Balogh, S and Murphy, DJ (2009) What is the minimum EROI that a sustainable society must have? Energies 2(1), 2547. https://doi.org/10.3390/en20100025CrossRefGoogle Scholar
Hall, CAS, Powers, R and Schoenberg, W (2008). Peak oil, EROI, investments and the economy in an uncertain future. In Pimentel, D (ed.), Biofuels, Solar and Wind as Renewable Energy Systems: Benefits and Risks. New York: Springer, pp. 109132.CrossRefGoogle Scholar
Hallock, JL Jr, Tharakan, PJ, Hall, CA, Jefferson, M, Wu, W (2004) Forecasting the limits to the availability and diversity of global conventional oil supply. Energy 29(11), 16731696.CrossRefGoogle Scholar
Hammond, ST, Brown, JH, Burger, JR, Flanagan, TP, Fristoe, TS, Mercado-Silva, N, Nekola, JC and Okie, JG (2015) Food spoilage, storage, and transport: Implications for a sustainable future. Bioscience 65(8), 758768. https://doi.org/10.1093/biosci/biv081CrossRefGoogle Scholar
Horton, BP, Rahmstorf, S, Engelhart, SE and Kemp, AC (2014) Expert assessment of sea-level rise by AD 2100 and AD 2300. Quaternary Science Reviews 84, 16. https://doi.org/10.1016/j.quascirev.2013.11.002CrossRefGoogle Scholar
Hoyos, C, Agudelo, P, Webster, P and Cury, J (2006) Deconvolution of the factors contributing to the increase in global hurricane intensity. Science 312, 9497.CrossRefGoogle Scholar
Hughes, HB, Breshears, DD, Cook, KJ, Keith, L and Burger, JR (2023) Household energy use response to extreme heat with a biophysical model of temperature regulation: An Arizona case study. PLOS Climate 2(4), e0000110. https://doi.org/10.1371/journal.pclm.0000110CrossRefGoogle Scholar
IEA 2013 “World Energy Outlook 2013.” Available at https://iea.blob.core.windows.net/assets/a22dedb8-c2c3-448c-b104-051236618b38/WEO2013.pdf (accessed April 2023).Google Scholar
IEA 2017 “World Energy Outlook 2017: A World in Transformation.” Available at https://www.iea.org/reports/world-energy-outlook-2017 (accessed April 2023).Google Scholar
IEA 2021 World Energy Outlook 2021, Part of World Energy Outlook. Available at https://www.iea.org/reports/world-energy-outlook-2021 (accessed April 2023).Google Scholar
IPCC (2013) Climate change 2013: The physical science basis. In Contribution of Working Group 1 to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. London: Intergovernmental Panel on Climate Change.Google Scholar
IPCC (2022) Climate change 2022: Impacts, adaptation and vulnerability. In Working Group II Contribution to the IPCC Sixth Assessment Report. Available at https://www.ipcc.ch/report/ar6/wg2/ (accessed April 2023).Google Scholar
Jackson, W and Jensen, R (2022) An Inconvenient Apocalypse. Notre Dame, IN: University of Notre Dame Press.Google Scholar
Jacobson, MZ, Delucchi, MA, Bazouin, G, Bauer, ZA, Heavey, CC, Fisher, E, Morris, SB, Piekutowski, DJ, Vencill, TA, Yeskoo, TW (2015a) 100% clean and renewable wind, water, and sunlight (WWS) all-sector energy roadmaps for the 50 United States. Energy & Environmental Science 8(7), 20932117. https://doi.org/10.1039/C5EE01283JCrossRefGoogle Scholar
Jacobson, MZ, Delucchi, MA, Cameron, MA and Frew, BA (2015b). Low-cost solution to the grid reliability problem with 100% penetration of intermittent wind, water, and solar for all purposes. Proceedings of the National Academy of Sciences 112(49), 1506015065. https://doi.org/10.1073/pnas.1510028112CrossRefGoogle Scholar
Kaufmann, RK, Kauppi, H, Mann, ML, Stock, JH (2011) Reconciling anthropogenic climate change with observed temperature 1998–2008. Proceedings of the National Academy of Sciences 108(29), 1179011793. https://doi.org/10.1073/pnas.1102467108CrossRefGoogle ScholarPubMed
Kemp, L, Xu, C, Depledge, J, Ebi, KL, Gibbins, G, Kohler, TA, Rockstrom, J, Scheffer, M, Schellnhuber, HJ, Steffen, W and Lenton, TM (2022) Climate endgame: Exploring catastrophic climate change scenarios. Proceedings of the National Academy of Sciences 119(34), e2108146119. https://doi.org/10.1073/pnas.2108146119CrossRefGoogle ScholarPubMed
Kirezci, E, Young, IR, Ranasinghe, R, Muis, S, Nicholls, RJ, Lincke, D and Hinkel, J (2022) Projections of global-scale extreme sea levels and resulting episodic coastal flooding over the 21st century. Nature Scientific Reports 10, 11629. https://doi.org/10.1038/s41598-020-67736-6CrossRefGoogle Scholar
Kopp, RE, Kemp, AC, Bittermann, K, Horton, BP, Donnelly, JP, Gehrels, WR, Hay, CC, Mitrovica, JX, Morrow, ED and Rahmstorf, S (2016) Temperature-driven global sea-level variability in the common era. Proceedings of the National Academy of Sciences 113(11), E1434E1441. https://doi.org/10.1073/pnas.1517056113CrossRefGoogle ScholarPubMed
Kraaijenbrink, PD, Bierkens, MF, Lutz, AF and Immerzeel, WW (2017) Impact of a global temperature rise of 1.5 degrees Celsius on Asia’s glaciers. Nature 549(7671), 257260.CrossRefGoogle ScholarPubMed
Kummu, M, de Moel, H, Salvucci, G, Viviroli, D, Ward, PJ and Varis, O (2022) Over the hills and further away from the coasts: Global geospatial patterns of human and environment over the 20th-21st centuries. Environmental Research Letters 11, 034010. https://doi.org/10.1088/1748-9326/11/034010CrossRefGoogle Scholar
Laherrère, J, Hall, CA and Bentley, R (2022) How much oil remains for the world to produce? Comparing assessment methods, and separating fact from fiction. Current Research in Environmental Sustainability 4, 100174. https://doi.org/10.1016/j.crsust.2022.100174CrossRefGoogle Scholar
Lambert, JG, Hall, CA, Balogh, S, Gupta, A and Arnold, M (2014) Energy, EROI and quality of life. Energy Policy 64, 153167.CrossRefGoogle Scholar
Li, L and Chakraborty, P (2020) Slower decay of landfalling hurricanes in a warming world. Nature 587(7833), 230234.CrossRefGoogle Scholar
Loeb, NG, Johnson, GC, Thorsen, TJ, Lyman, JM, Rose, FG and Kato, S (2021) Satellite and ocean data reveal marked increase in Earth’s heating rate. Geophysical Research Letters 48(13), e2021GL093047.CrossRefGoogle Scholar
Maggio, G and Cacciola, G (2012) When will oil, natural gas, and coal peak? Fuel 98, 111123.CrossRefGoogle Scholar
Marshall, Z and Brockway, P (2020) A net energy analysis of the global agriculture, aquaculture, fishing and forestry system. Biophysical Economics and Sustainability 5, 9. https://doi.org/10.1007/s41247-020-00074-3CrossRefGoogle Scholar
McGuire, B (2022) Hothouse Earth. London: Icon Books.Google Scholar
Mei, J, Leung, NL, Kwok, RT, Lam, JW and Tang, BZ (2015) Aggregation-induced emission: Together we shine, united we soar! Chemical Reviews 115(21), 1171811940. https://doi.org/10.1021/acs.chemrev.5b00263CrossRefGoogle ScholarPubMed
Min, SK, Zhang, X, Zwiers, FW and Hegerl, GC (2011) Human contribution to more-intense precipitation extremes. Nature 470, 378381.CrossRefGoogle ScholarPubMed
Mohr, SH, Wang, J, Ellem, G, Ward, J and Giurco, D (2015) Projection of world fossil fuels by country. Fuel 141, 120135. https://doi.org/10.1016/j.fuel.2014.10.030CrossRefGoogle Scholar
Mora, C, Dousset, B, Caldwell, IR, Powell, FE, Geronimo, RC, Bielecki, CR, Counsell, CW, Dietrich, BS, Johnston, ET, Louis, LV and Lucas, MP (2017) Global risk of deadly heat. Nature Climate Change 7(7), 501506.CrossRefGoogle Scholar
Murphy, DJ and Hall, CAS (2011) Energy return on investment, peak oil, and the end of economic growth. Annals of the New York Academy of Sciences 1219(1), 5272. https://doi.org/10.1111/j.1749-6632.2010.05940.xCrossRefGoogle ScholarPubMed
Mushalik, M (2021) Peak oil in South and Central America. Available at https://www.resilience.org (accessed 21 October 2022).Google Scholar
Oliver, EC, Benthuysen, JA, Darmaraki, S, Donat, MG, Hobday, AJ, Holbrook, NJ, Schlegel, RW, and Sen Gupta, A (2021) Marine heatwaves. Annual Review of Marine Science 13(1), 313342. https://doi.org/10.1146/annurev-marine-032720-095144CrossRefGoogle ScholarPubMed
Oppenheimer, M, Glavovic, BC, Hinkel, J, van de Wal, R, Magnan, AK, Abd-Elgawad, A, et al. 2019. 4. Sea level rise and implications for low-Lying Islands, coasts and communities.” In The Ocean and Cryosphere in a Changing Climate: Special Report of the Intergovernmental Panel on Climate Change, Edited by Intergovernmental Panel on Climate Change (IPCC). Cambridge: Cambridge University Press, pp. 321446. https://doi.org/10.1017/9781009157964.006Google Scholar
Pall, P, Aina, T, Stone, DA, Stott, PA, Nozawa, T, Hilberts, AG, Lohmann, D and Allen, MR (2011) Anthropogenic greenhouse gas contribution to flood risk in England and Wales in autumn 2000. Nature 470(7334), 382385.CrossRefGoogle ScholarPubMed
Pauly, D and Yanez-Arancibia, A (2013) Fisheries in Lagoon-Estuarine. In Day, JW, Crump, BC, Kemp, WM and Yanez-Arancibia, A (eds.), Estuarine Ecology. Hoboken, NJ: Wiley-Blackwell, pp. 465482.Google Scholar
Pfeffer, WT, Harper, JT and O’Neel, S (2008) Kinematic constraints on glacier contributions to 21st-century sea-level rise. Science 321(5894), 13401343.CrossRefGoogle ScholarPubMed
Rockstrom, J, et al. (2009) A safe operating space for humanity. Nature 461(24), 472475.CrossRefGoogle ScholarPubMed
Schiermeier, Q (2011) Increased flood risk linked to global warming. Nature 470(7334), 316316.CrossRefGoogle ScholarPubMed
Schramski, J, Woodson, C, Steck, G, Munn, D and Brown, J (2019) Declining country-level self-sufficiency suggests future food insecurities. Biophysical Economics and Resource Quality 4, 12. https://doi.org/10.1007/s41247-019-0060-0CrossRefGoogle Scholar
Schramski, J, Woodson, C. and Brown, J. (2020) Energy use and the sustainability of intensifying food production. Nature Sustainability 31, 257259. https://doi.org/10.1038/s41893-020-0503-zCrossRefGoogle Scholar
Sgouridis, S, Csala, D and Bardi, U (2016) The sower’s way: Quantifying the narrowing net-energy pathways to a global energy transition. Environmental Research Letters 11, 094009. https://doi.org/10.1088/1748-9326/11/9/094009CrossRefGoogle Scholar
Smil, V (2022) How the World Really Works: The Science behind how we Got Here and where We’re Going. London: Viking.Google Scholar
Steffen, W, Richardson, K, Rockström, J, Cornell, SE, Fetzer, I, Bennett, EM, Biggs, R, Carpenter, SR, De Vries, W, De Wit, CA and Folke, C (2015) Planetary boundaries: Guiding human development on a changing planet. Science 347(6223), 1259855. https://doi.org/10.1126/science.1259855CrossRefGoogle ScholarPubMed
Stott, PA, Stone, DA and Allen, MR (2004) Human contribution to the European heatwave of 2003. Nature 432(7017), 610614.CrossRefGoogle Scholar
Suárez-Ruiz, I, Diez, MA and Rubiera, F (2019) 1 - Coal. New Trends in Coal Conversion, 1–30. https://doi.org/10.1016/B978-0-08-102201-6.00001-7CrossRefGoogle Scholar
Syvitski, J, Waters, CN, Day, J, Milliman, JD, Summerhayes, C, Steffen, W, Zalasiewicz, J, Cearreta, A, Gałuszka, A, Hajdas, I and Head, MJ (2020) Extraordinary human energy consumption and resultant geological impacts beginning around 1950 CE initiated the proposed Anthropocene epoch. Communications Earth & Environment 1(1), 32. https://doi.org/10.1038/s43247-020-00029-yCrossRefGoogle Scholar
Syvitski, JP, Kettner, AJ, Overeem, I, Hutton, EW, Hannon, MT, Brakenridge, GR, Day, JW, Vörösmarty, C, Saito, Y, Giosan, L and Nicholls, RJ (2009) Sinking deltas due to human activities. Nature Geoscience 2(10), 681686. https://doi.org/10.1038/ngeo629CrossRefGoogle Scholar
Syvitski, J, Anthony, E, Saito, Y, Zainescu, F, Day, JW, Bhattacharya, J and Giosan, L (2022) Large deltas, small deltas: Toward a more rigorous understanding of coastal marine deltas. Global and Planetary Change 218, 103958. https://doi.org/10.1016/j.gloplacha.2022.103958CrossRefGoogle Scholar
Tainter, JA (1988) Collapse of Complex Societies. Cambridge: Cambridge University Press.Google Scholar
Tainter, JA (2005). Ecological vs. social complexity: An anthropological perspective on a science of sustainability. Presented in the Anthropology Colloquium Series and the International Institute for Sustainability Wrigley Lecture Series on Sustainability. Tempe: Arizona State University.Google Scholar
Tessler, ZD, Vörösmarty, CJ, Grossberg, M, Gladkova, I, Aizenman, H, Syvitski, JP, and Foufoula-Georgiou, E (2015). Profiling risk and sustainability in coastal deltas of the world. Science 349(6248), 638643. https://doi.org/10.1126/science.aab3574CrossRefGoogle ScholarPubMed
United Nations (2022) Department of Economic and Social Affairs, Population Division World Population Prospects 2022. Available at https://population.un.org/wpp/ (accessed April 2023).Google Scholar
USGS (2003) World Petroleum Assessment 2000 (Electronic Resource) . Reston, VA: U.S. Dept. of the Interior, U.S. Geological Survey. Available at https://pubs.usgs.gov/fs/fs-062-03/FS-062-03.pdf (accessed April 2023).Google Scholar
Vermeer, M and Rahmstorf, S (2009) Global Sea level linked to global temperature. Proceedings of the National Academy of Sciences 106(51), 2152721532. https://doi.org/10.1073/pnas.0907765106CrossRefGoogle ScholarPubMed
Warr, BS and Ayres, RU (2010) Evidence of causality between the quantity and quality of energy consumption and economic growth. Energy 35(4), 16881693. https://doi.org/10.1016/j.energy.2009.12.017CrossRefGoogle Scholar
Webster, PJ, Holland, GJ, Curry, JA and Chang, HR (2005) Changes in tropical cyclone number, duration, and intensity in a warming environment. Science 309(5742), 18441846.CrossRefGoogle Scholar
Xu, C, Kohler, TA, Lenton, TM, Jens-Christian, S and Scheffer, M (2020) Future of the human climate niche. Proceedings of the National Academy of Sciences 117, 1135011355. https://doi.org/10.1073/pnas.1910114117CrossRefGoogle ScholarPubMed
Zhang, P, Jeong, JH, Yoon, J, Hy, Kim, Wang, SS, Linderholm, HW, Fang, K, Xiuchen, W and Deliang, C (2020) Abrupt shift to hotter and drier climate over inner East Asia beyond the tipping point. Science 370(6520), 10951099. https://doi.org/10.1126/science.abb3368CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. The current global distribution of coastal urban areas larger than 100,000 people. Many of the largest cities are in lower income, tropical to subtemperate coastal regions including tropical Africa, South and Southeast Asia, Central America, and the Caribbean (C40.org 2020). The coastal zones enclosed within the dotted lines area are projected to experience multiple climate stresses that will interact with social, political, and economic megatrends that will likely lead to diminished resilience and sustainability (Modified from C40.org 2020 by Day et al., 2021. Used with permission).

Figure 1

Table 1. Top 25 largest megacities of the world as of October 2022 (modified from United Nations, 2022)

Figure 2

Figure 2. Growth of world energy production and GDP from 1830 to 2008. “Other” includes solar, wind, and other new renewables (Murphy and Hall, 2011, used with permission).

Figure 3

Figure 3. World Primary Energy Consumption by Percent Fuel Type from (a) 1980, (b) 2000, (c) 2020 (Source: Modified from BP Statistical Review of World Energy 2021), and (d) projection to 2050. The total energy consumption is 279.4 EJ, 394.5 EJ, 557.1 EJ, and 589.7 EJ for the corresponding years, respectively (Source: calculated from BP Statistical Review of World Energy 2021 for 1980, 2000, 2020, and DNV, Energy Transition Outlook, 2021 for 2050 – estimated).

Figure 4

Figure 4. Major coal fields of the world (Suárez-Ruiz et al., 2019). Most are far from coasts. Used with permission.

Figure 5

Figure 5. Major oil and gas fields of the world. Oil endowment (cumulative production plus remaining reserves and undiscovered resources) for provinces assessed (from USGS, 2003). Darker green indicates more resources. Measured regions include (1) the former Soviet Union, (2) the Middle East and North Africa, (3) Asia-Pacific, (4) Europe, (5) North America, (6) Central and South America, (7) sub-Saharan Africa and Antarctica, and (8) South Asia (USGS, 2003). Alaska and the U.S. Gulf coast are not shown here. Red lines indicate the location of the edge of the continental shelf. Used with permission.

Figure 6

Figure 6. Major food-producing areas of the world. Used with permission.

Author comment: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR1

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr1 [Opens in a new window]
John. W Day [Opens in a new window] Oceanography and Coastal Sciences, Louisiana State University, United States
Revision round: 0
Role: author

Comments

We are submitting the attached manuscript The Coming Perfect Storm: Diminishing Sustainability of Coastal Human-Natural Systems in the Anthropocene for publication in Coastal Prisms/Coastal Futures. This is an invited submission. The paper is a comprehensive review of factors affecting coastal human and natural systems in the Anthropocene as impacted by climate change, energy resources, and current and alternative views of the economy. Because we suggest alternative views to current thinking, especially contemporary neoclassical economics, we have suggested reviewers familiar with these issues. We conclude that the current trajectories of coastal human and natural systems are profoundly unsustainable and there will be great difficulties in the transition to a renewable system.

Figure and tables are included in the text of the manuscript. Permissions to use figures is in process. All authors contributed to the conceptualization and writing of the paper. The authors declare no conflict of interest. No sponsored funding was used specifically for the preparation of the paper.

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR2

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr2 [Opens in a new window]
Mark Brown [Opens in a new window] Environmental Engineering Sciences, University of Florida, United States
Date of review:  16 December 2022
Revision round: 0
Role: reviewer
Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

I suggest that the authors carefully read the manuscript, as I found numerous dropped conjunctions and prepositions. Often paragraphs end with the topic sentences rather than beginning with them. Many paragraphs seem to have no topic sentence and are compilations of facts and figures strung together.

The following are some specific examples and suggestions.

Awkward phrase…meaning unclear. “This has profound implications for the renewable transition as FFs underwrite more than 80% of societal, including the transition to a renewable economy.”

Awkward phrase…During the Holocene, the earth warmed and became wetter became more productive.

Awkward…“Even with rapid renewables growth” how about, Even with the rabid growth of renewable energy…?

Awkward… “Thus, FFs are still supporting most economic activity including renewable energy development, dealing with the economic impacts of climate change, as well as maintenance of infrastructure, and consumption of staples and discretionary spending”….. Do FFs deal with economic impacts?

Figure 2 is a bit old…doesn’t show the economic/energetic downturn of the great recession (or recent Covid downturn) a fact that might help to make your point about the coupling of economy and energy. Aa more up to date graph would be useful.

Beginning on page 6 – LaHerrere et al. 2022- seems like too much detail. A summary of key finding would be enough.

“There have been a number of projections [of] future energy use where renewables are included. IEA (2013) reported that FFs provided about 83% of total primary energy in 2011 (Figure 3). “ There is no 2011 in Figure 3. And the data given in Figure 3 is from BP, not IEA.

“Rapidly moving to lower Energy Return on Investment (EROI) …” most interesting statement. It would be important to provide some background on these lower EROIs. This is the first the reader is introduced to such an important concept.

Awkward phraseology, meaning not clear…”The transition to renewable energy would require the allocation of 5% of U.S. 2016 GDP to renewable energy between 2025-2040 (Jacobson et al. 2015a,b), in addition to decommissioning FF infrastructure and FFs to provide remaining net energy requirements. “

The first sentence in section titled “Economics: The failure of NCE… “How, especially, could we design such a future that would be more sustainable in a world challenged by environmental deterioration, climate change, resource scarcity, and the coming end of the fossil fuel era?” … suggests that you are about to provide some insights on planning for the future…However instead, this section of the paper delves into a critique of NCE and a suggestion for a rapid transition to BPE. While I agree, a new economic is needed, it would be nice for other readers to understand a bit more how the transition to BPE would help with the major problems you have done such a good job elucidating.

“These increased costs will weigh heavily on the economy, especially in coastal regions in developing countries.” ….Why especially in coastal regions?

Unclear meaning….There will be sufficient FFs used to lead to all but the worst climate impacts.

The last sentence in the abstract suggests that ultimately after numerous pages of rehashing the present and future problems of global energy estimates, neoclassical economics and climate impacts on the coastal zone, that some suggestions, or at the very least some thoughts on potential scenarios for “careful planning and cooperation” that might “minimize impacts of these changes” might be offered. When I reached the final paragraph, I was surprised, and a bit let down. “It seems inevitable that past patterns of energy use, resource consumption, and economic growth cannot be sustained”….and so?

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR3

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr3 [Opens in a new window]
Reviewer_1
Date of review:  25 March 2023
Revision round: 0
Role: reviewer
Recommendation/decision: accept

Conflict of interest statement

Reviewer declares none.

Comments

Excellent review. Ready to publish as is with minor grammar corrections. However, in my opinion the analysis of neoclassical economics should lead and the review be restructured based on this lead idea.

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR4

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr4 [Opens in a new window]
Date of review:  29 March 2023
Revision round: 0
Role: reviewer
Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

This is a very interesting paper that makes a complete review of major issues related climate change effects on coastal zones.

I consider that the last paragraph are the conclusions of the paper and may be a subtitle for this section.

Recommendation: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR5

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr5 [Opens in a new window]
Tom Spencer [Opens in a new window] Geography, Cambridge University, United Kingdom of Great Britain and Northern Ireland
Date of review:  31 March 2023
Revision round: 0
Role: Handling Editor
Recommendation/decision: major-revision

Comments

There are three reviews here but only Reviewer 1 provides a thorough – and useful - review. (I comment on the restructuring around NCE suggested by Reviewer 2 towards the end of this response - where I also cover the Reviewer 3 comment). I agree with the introductory comments of Reviewer 1 and that the manuscript needs some re-structuring of sentences in places. There is also a tendency to be rather too list-like in places, with some over-referencing. Are 17 references really needed at the bottom of page 3 / top of page 4? In summary, there is a really good review paper here but it tends to get lost in long general arguments (the arguments in themselves are good…) and a lack of coastal focus. In particular the end of the review is disappointing. I know that it is easier to identify how we have got to where we are but I do think that there needs to be rather more on where we could go in the near-future, based around what has gone before in the review. This addition, in my view, is a critical need for manuscript acceptance – and pushes the changes asked for to ‘major revision’. I concur with the final comments of Reviewer 1 here.

Under ‘Coastal Climate Change Impacts’ there is no need to repeat the benign Holocene argument as this is covered in the Introduction. It is important here to concentrate on coasts and so I do wonder if the paragraph beginning on line 3 on page 4 (22 lines) might actually be condensed into a few lines that could go into the page 3 text on climate impacts. The megacities arguments in the next paragraph are repetition from page 2. The last paragraph of this section on page 5 seems repetitive too. So I think there is a bit of work to do in sharpening – and shortening - pages 2 to 5.

Under ‘Energy, The Renewable Transition, and the future of the world’s coast’, Reviewer 1 highlights some awkward phraseology and asks if an updated Figure 2 could be provided. Some work is also needed on Figure 3 and the related text. Again, I think it is important here to keep to general principles and not to go off into too much detail – a point made by Reviewer 1 for the bottom of page 6 to the start of the next sub-section. Reviewer 1 also asks for more on the EROI which seems reasonable. As none of pages 6, 7 and 8 have a coastal focus it is too long as it stands. At lines 6-9 on page 9 is a really perceptive statement about the place of coasts in this debate – could that not be developed further in a shorter overall section?

‘Economics: The Failure of Neoclassical and the Promise of Biophysical’. Reviewer 1 has some useful things to say here. I agree that his potential restructuring has merit- ‘how the transition to BPE would help with the major problems you have done such a good job elucidating’. There is a lot of text here before we get to BPE (pages 9 to 12) and sometimes I feel it covers the same ground in multiple ways. I quite understand that it is valuable – essential - to bring Howard Daly’s scholarship to this argument but I am less convinced that we have to have the broad historical view from Roy Harrod and Joan Robinson to Thomas Piketty. Could this material not be condensed down to a series of points, made only once? And why is the BPE section not referenced?

‘Provisioning of coastal social and economic systems’ seems to start by going back to the LaHerrere arguments on page 6 (and again on page 9). Could you not just refer back here and concentrate this section on food supply and trade (pages 14, 15)?

‘The World’s Coasts: Shifting Baselines and Diminishing Sustainability’. The first paragraph on page 16 is not needed as the argument really starts with the second paragraph. Or would it be better to move energy into this section, and the renewables transition down to end this history of the human occupancy and use of the coast (which would give the structure suggested by Reviewer 2)? The final paragraph on page 17 really has been said before (I think Reviewer 3 is asking for this paragraph to be formally recognised as a Conclusion). It is then a bit of a shock to suddenly get to ‘Literature cited’. The sense is that there is a missing section on possible coastal futures underpinned by ‘good’ economics and sensible resource use.

Decision: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R0/PR6

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr6 [Opens in a new window]
Janine Adams [Opens in a new window] Institute for Coastal and Marine Research, Nelson Mandela University, South Africa
Revision round: 0
Role: Editor in Chief
Recommendation/decision: major-revision

Comments

No accompanying comment.

Author comment: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R1/PR7

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr7 [Opens in a new window]
John. W Day [Opens in a new window] Oceanography and Coastal Sciences, Louisiana State University, United States
Revision round: 1
Role: author

Comments

Prog. Janine Adams

Editor-in-Chief, Cambridge Prisms: Coastal Futures.

Dear Professor Adams,

I am resubmitting our manuscript “The coming perfect storm: diminishing sustainability of coastal-human systems in the Anthropocene” (CFT-22-0057).

In revising the paper, we addressed all reviewer comments as well as those of Dr. Tom Spencer, the Handling Editor. Detailed responses to reviewer comments are also attached.

I apologize for the 2 week delay as my computer had a major crash just as we were starting the review and it required a major effort to recover all files.

Sincerely

John Day

Professor Emeritus

Dept. of Oceanography and Coastal Sciences

Louisiana State University

Baton Rouge, LA 70803

225-773-7165

[email protected]

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R1/PR8

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr8 [Opens in a new window]
Date of review:  09 June 2023
Revision round: 1
Role: reviewer
Recommendation/decision: accept

Conflict of interest statement

Reviewer declares none.

Comments

This is a very interesting and innovative paper Congratulations to the authors

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R1/PR9

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr9 [Opens in a new window]
Mark Brown [Opens in a new window] Environmental Engineering Sciences, University of Florida, United States
Date of review:  20 June 2023
Revision round: 1
Role: reviewer
Recommendation/decision: major-revision

Conflict of interest statement

I have professional relationship with CAS Hall. We have co-authored several papers. However, I do not believe it will influence my review.

Comments

Overall, the text needs more subheadings. As it is now, the text jumps from one subtopic to another and would benefit from subheadings. It would also benefit from careful editing to make sure paragraphs are constructed properly with topic sentences followed by a few sentences to further develop or support and ending with a summary/conclusion. Many paragraphs are upended by ending with a sentence about coastal systems that should be the first or topic sentence.

There is a lot of repetition. A good editing to remove it is recommended.

The section on economics that begins on page 9 shifts to 1st person plural following nine pages in the passive voice. And then the 1st person is largely dropped on page 10. While not a critical flaw, one wonders why suddenly it is important to make the shift and then to drop it again.

The discussion of neoclassical economics beginning on page 10, while interesting, is overly detailed and a bit wordy. It seems much of this is more appropriate for a textbook on biophysical economics and less for an article in Coastal Futures. With a little elaboration (an additional sentence or two) the bulleted text on page 9 could take the place of these 2 pages.

There are numerous occasions throughout the manuscript where an equivalency between money and energy are implied, in doing so it weakens the manuscript and serves to confuse the reader who may be uninitiated to BPE. Early in the manuscript money is defined as “abstract value” but as the manuscript progresses, it becomes increasingly difficult to tell if the authors are talking about investing abstract value or energy or GDP (another abstract notion of value). This is a fundamental flaw and needs to be addressed. Careful editing to remove them is warranted.

On several occasions an equivalency between less energy and increased inflation or investments in energy infrastructure and inflation are made. While some readers may be able to make the jump from less energy to increased inflation, many will not make that connection. More explanation is needed. Why does less energy drive inflation? Less energy in and of itself does not cause inflation, however, if the money supply is increased to offset the slowdown in the economy caused by less energy, inflation can occur. Investing money in energy infrastructure or environmental mitigation does not necessarily cause inflation…a careful explanation is needed.

I have numerous corrections and comments in a PDF of the manuscript which should be sent to the authors.

Recommendation: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R1/PR10

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr10 [Opens in a new window]
Tom Spencer [Opens in a new window] Geography, Cambridge University, United Kingdom of Great Britain and Northern Ireland
Date of review:  23 June 2023
Revision round: 1
Role: Handling Editor
Recommendation/decision: minor-revision

Comments

The reviews on the revision range from ‘accept’ to ‘major revision’. Having re-read the manuscript my assessment lies between these two decisions. I am also mindful of the fact that this paper has been in review for a long time and that you have made considerable changes already. It just needs one final push to get the ms into an acceptable shape now. The section on neoclassical economics and BPE (from line 34, page 9 to line 30, page 13) remains too long and unbalances the overall structure of the paper. I agree with Reviewer 2 on this point although reducing everything down to largely the page 9 bullet points is not reasonable. But could you aim for one page on NCE and one page on BPE please? The other major point raised by Reviewer 2 is the question of equivalency between energy and money and energy and inflation relations (particularly around pages 13-14). That material does need some attention. It would be helpful to move the coastal justifications from the ends of paragraphs to the beginnings. The marked PDF helpfully highlights some repetition, unfinished sentences, lapses in style and shifts in tense which need attention – but these changes should not take up too much time.

Decision: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R1/PR11

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr11 [Opens in a new window]
Janine Adams [Opens in a new window] Institute for Coastal and Marine Research, Nelson Mandela University, South Africa
Revision round: 1
Role: Editor in Chief
Recommendation/decision: minor-revision

Comments

No accompanying comment.

Author comment: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R2/PR12

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr12 [Opens in a new window]
John. W Day [Opens in a new window] Oceanography and Coastal Sciences, Louisiana State University, United States
Revision round: 2
Role: author

Comments

Dear Editor, we are resubmitting our manuscript “The coming perfect storm:Diminishing sustainability of coastal-human systems in the Anthropocene”. In revising the paper, we have significantly revised the manuscript and responded to all reviewer comments. These are included in the response to reviewers section.

Sincerely,

John Day

Dept. of Oceanography and Coastal Sciences

Louisiana State University

Baton Rouge, LA 70803 USA

Review: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R2/PR13

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr13 [Opens in a new window]
Mark Brown [Opens in a new window] Environmental Engineering Sciences, University of Florida, United States
Date of review:  17 July 2023
Revision round: 2
Role: reviewer
Recommendation/decision: accept

Conflict of interest statement

Stated previously

Comments

For the most part, I accept the edits/changes by the authors...they have improved the manuscript considerably.

Recommendation: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R2/PR14

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr14 [Opens in a new window]
Tom Spencer [Opens in a new window] Geography, Cambridge University, United Kingdom of Great Britain and Northern Ireland
Date of review:  17 July 2023
Revision round: 2
Role: Handling Editor
Recommendation/decision: accept

Comments

I have been through the response to reviewer comments alongside the revised manuscript. The review of R1 highlighted the need to shorten the section on neoclassical economics and BPE. This has been done; the section is now 50% shorter than its previous length, without loss of impact. The review of R1 also highlighted the difficulty of the equivalence between energy and money. All this problematic text has been removed. These changes significantly rebalance the paper into a much more readable and better argued whole. In addition, some 16 more minor points have been attended to in full. I am completely satisfied that this is a serious and constructive revision. My decision is ‘accept’.

Decision: The coming perfect storm: Diminishing sustainability of coastal human–natural systems in the Anthropocene — R2/PR15

Published online by Cambridge University Press:  10 August 2023
DOI: https://doi.org/10.1017/cft.2023.23.pr15 [Opens in a new window]
Janine Adams [Opens in a new window] Institute for Coastal and Marine Research, Nelson Mandela University, South Africa
Revision round: 2
Role: Editor in Chief
Recommendation/decision: accept

Comments

No accompanying comment.