Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-26T00:13:34.395Z Has data issue: false hasContentIssue false
  • English
  • Français

Climate change and human security in coastal regions

Published online by Cambridge University Press:  12 February 2024

Jan Petzold Open the ORCID record for Jan Petzold [Opens in a new window]  and
Jürgen Scheffran Open the ORCID record for Jürgen Scheffran [Opens in a new window]
Jan Petzold*
Affiliation:
Department of Geography, Ludwig-Maximilians-Universität München, München, Germany
Jürgen Scheffran
Affiliation:
Research Group Climate Change and Security, Institute of Geography, Center for Earth System Research and Sustainability, University of Hamburg, Hamburg, Germany
*
Corresponding author: Jan Petzold; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Climate change has been recognised as a major concern in coastal hotspots exposed to multiple climate hazards under regionally specific characteristics of vulnerability. We review the emerging research and current trends in the academic literature on coastal climate risk and adaptation from a human security perspective. The ecological and socioeconomic developments are analysed for key risk areas, including coastal infrastructure; water, food and fisheries; health; human mobility; and conflict, taking the different geographical contexts of coastal areas in islands, megacities and deltas into consideration. Compounding and cascading interactions require integrative research and policy approaches to address the growing complexity. Governance mechanisms focus on coastal management and adaptation, nature-based solutions and community-based adaptation, considering their synergies and trade-offs. This perspective allows for a holistic view on climate risks to human security and vicious circles of societal instability in coastal systems and the interconnectedness of different risk dimensions and systems necessary for sustainable and transformative adaptation solutions for the most affected coastal hotspots.

Topics structure

Topic(s)

Climate change

Subtopic(s)

Impacts on coastal communities

Keywords

climate change adaptationcoastal vulnerabilitycoastal protectionhuman securitysea level rise
Type
Review
Information
Cambridge Prisms: Coastal Futures , Volume 2 , 2024 , e5
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NC
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial licence (http://creativecommons.org/licenses/by-nc/4.0), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original article is properly cited. The written permission of Cambridge University Press must be obtained prior to any commercial use.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Impact statement

Building on the growing body of literature on climate risk in coastal areas, this review provides a conceptual contribution and an integrated perspective through the lens of human security, examining multifaceted climate impacts and systemic risks to the vital core of human lives in different coastal contexts. Results are synthesised across coastal hotspots in islands, coastal megacities and river deltas exposed to local environmental and global climate hazards, threatening human life, health and infrastructure. In the underlying complex interconnections of coasts with land, sea and rivers, climate change acts as a threat multiplier in water, food and fishery, mobility and conflict, resulting in vicious circles of compounding and cascading impacts with severe risks to human security and societal stability, especially for marginalised communities. Contributing a deeper understanding of these interactions and trends, this research provides opportunities for understanding of emerging crises and solutions in adaptive governance and resilience across multiple scales, integrating coastal management, nature-based solutions and community-based adaptation adequate to the respective geographical coastal environments.

Introduction

Human populations in coastal areas are at increasing risk from climate change due to the interplay of coast-specific hazards and anthropogenic dynamics affecting their exposure and vulnerability (Magnan et al., Reference Magnan, Garschagen, Gattuso, Hay, Hilmi, Holland, Isla, Kofinas, Losada, Petzold, Ratter, Schuur, Tabe, Van de Wal, Pörtner, Roberts, Masson-Delmotte and Weyer2019; Glavovic et al., Reference Glavovic, Dawson, Chow, Garschagen, Haasnoot, Singh, Thomas, Pörtner, Roberts, Tignor and Rama2022). Coastal climate risk results, on the one hand, from exposure to hazards such as sea level rise and tropical cyclones, causing erosion and flooding. According to current projections global mean sea level rises by 0.38 m to 0.77 m by 2100 (Fox-Kemper et al., Reference Fox-Kemper, Hewitt, Xiao, Adalgeirsdottir, Drijfhout, Edwards, Golledge, Hemer, Kopp, Krinner, Mix, Notz, Nowicki, Nurhati, Ruiz, Sallee, Slangen, Yu, Masson-Delmotte, Zhai, Pirani and Zhou2021). The frequency of intense tropical cyclones is expected to increase in many regions (Seneviratne et al., Reference Seneviratne, Zhang, Adnan, Badi, Dereczynski, Di Luca, Ghosh, Iskandar, Kossin, Lewis, Otto, Pinto, Satoh, Vicente-Serrano, Wehner, Zhou, Masson-Delmotte, Zhai, Pirani and Zhou2021), with potentially severe consequences for different dimensions of human security (Ortiz et al., Reference Ortiz, Chua, Salvador, Dyngeland, Albao and and Abesamis2023a). On the other hand, exposure and vulnerability to these hazards are shaped by socioeconomic factors, infrastructure development, urbanisation, migration, demographic change and exploitation of coastal resources. Around 1 billion people already live in the so-called Low-Elevation Coastal Zone (LECZ), and the number is increasing, especially in urban areas (MacManus et al., Reference MacManus, Balk, Engin, McGranahan and Inman2021).

Climate risk is context-specific and heterogeneous across global coasts. Hotspots of coastal climate risk include small islands, river deltas and megacities (Magnan et al., Reference Magnan, Garschagen, Gattuso, Hay, Hilmi, Holland, Isla, Kofinas, Losada, Petzold, Ratter, Schuur, Tabe, Van de Wal, Pörtner, Roberts, Masson-Delmotte and Weyer2019). These hotspots share a high exposure to climate hazards due to their topography and concentration of high-value assets and infrastructures, and a high vulnerability due to high rates of poverty, unequal income distribution, insecure livelihoods, reliance on natural resources and pressures to local cultures and traditions of living by the and with the sea (Gillis, Reference Gillis2012; Glaser et al., Reference Glaser, Christie, Diele, Dsikowitzky, Ferse, Nordhaus, Schlüter, Schwerdtner Mañez and Wild2012; Spalding and Biedenweg, Reference Spalding and Biedenweg2017).

Compared to the dominant conceptions of climate vulnerability and risk, human security perspectives found less attention in climate change scholarship over the past decades, particularly in coastal contexts. At the same time, there has been an increasing focus on coastal risk and adaptation, including a Special Report on the Ocean and Cryosphere in a Changing Climate by the Intergovernmental Panel on Climate Change (IPCC) with a dedicated focus on coastal systems (IPCC, Reference Pörtner, Roberts and Masson-Delmotte2019). Therefore, the main focus of this review is to translate the general human security perspective on livelihoods, culture, migration, conflict and geopolitics (Adger et al., Reference Adger, Pulhin, Barnett, Dabelko, Hovelsrud, Levy, Oswald Spring, Vogel, Field, Barros, Dokken and White2014) to the coastal risk context (see Figure 1). Specifically, we focus on five dimensions of coastal human security risks which have been extensively discussed in the Sixth Assessment Report of the IPCC: Coastal critical infrastructure; water, food and fisheries; human wellbeing and health; human mobility and displacement; societal stability and conflict. We use this coastal human security lens to assess the main streams in recent academic literature with respect to three geographical units with particular vulnerability to climate change (islands; coastal settlements and megacities; river deltas and estuaries) and four interconnected realms of adaptation that combine a wide range of complementary response mechanisms affecting key natural and societal processes (coastal governance; management and protection; nature-based solutions; community-based adaptation). Moreover, this review aims at highlighting the value of a human security lens on future coastal climate risk.

Figure 1. Framework for coastal human security assessments, building on translated general human security dimensions (Adger et al., Reference Adger, Pulhin, Barnett, Dabelko, Hovelsrud, Levy, Oswald Spring, Vogel, Field, Barros, Dokken and White2014) into specific dimensions of human security for coastal hotspots in this review.

Climate vulnerability and coastal risks in human security perspectives

Coastal risks to climate change can build on concepts of vulnerability, exposure, hazard, risk and adaptation defined by the IPCC (Reference Pörtner, Roberts and Tignor2022). Vulnerability is the “propensity or predisposition to be adversely affected, which encompasses a variety of concepts and elements including sensitivity or susceptibility to harm and lack of capacity to cope and adapt” (IPCC, Reference Pörtner, Roberts and Tignor2022, p. 2927). This is relevant for exposure to hazards “that may cause loss of life, injury or other health impacts, as well as damage and loss to property, infrastructure, livelihoods, service provision, ecosystems and environmental resources” (IPCC, Reference Pörtner, Roberts and Tignor2022, p. 2911). While impacts are the consequences of interactions between climate-related hazards, exposure and vulnerability, risk is the “potential for adverse consequences for human or ecological systems, recognising the diversity of values and objectives associated with such systems” (IPCC, Reference Pörtner, Roberts and Tignor2022, p. 2921) which is subject to uncertainty in magnitude and likelihood of occurrence. Recently, also the term “severe” climate risk has been introduced, defined by “the physical and socio-ecological thresholds leading to transformational and possibly abrupt changes; the irreversibility of these changes; and the cascading effects within and across the affected systems” (Magnan et al., Reference Magnan, O’Neill and Garschagen2023b). Adaptation is “the process of adjustment to actual or expected climate and its effects, in order to moderate harm or exploit beneficial opportunities” (IPCC, Reference Pörtner, Roberts and Tignor2022, p. 2898).

While these terms largely refer to a system perspective of causes and effects of climate change, human security is centred on the security and welfare of human beings as affected and responding agents, different from national and international security, which are the domain of governments and the military (for an overview, see Brauch and Scheffran, Reference Brauch, Scheffran, Scheffran, Brzoska, Brauch, Link and Schilling2012). One approach to human security is based on “shielding people from acute threats and empowering people to take charge of their own lives” (CHS, 2003, p. iv). According to the IPCC (Reference Pörtner, Roberts and Tignor2022, p. 2911), human security is a “condition that is met when the vital core of human lives is protected, and when people have the freedom and capacity to live with dignity.” In the context of climate change, the vital core of human lives includes “the universal and culturally specific, material and non-material elements necessary for people to act on behalf of their interests and to live with dignity.” (IPCC, Reference Pörtner, Roberts and Tignor2022, p. 2911).

Following this definition, protection against various adverse impacts, risks and threats to the “vital core of human lives” can be considered, from violent conflict, lack of human rights and development to environmental and climate risks for lives and livelihoods. Building on the concepts mentioned above, the following sections synthesise the current research trends on human security concerns considering diverse climate-related coastal hazards, security dimensions and coastal hotspots.

Human security risks in coastal regions

Coastal critical infrastructures

Climate-related hazards are projected to increase marine heatwaves, rising sea levels and extreme precipitation events that have high impacts in coastal zones (Collins et al., Reference Collins, Sutherland, Bouwer, Cheong, Frolicher, Jacot Des Combes, Koll Roxy, Losada, McInnes, Ratter, Rivera-Arriaga, Susanto, Swingedouw, Tibig, Pörtner, Roberts, Masson-Delmotte and Weyer2019). Coastal urban centres are agglomerations of dense settlements, high-value assets and real estate, as well as critical infrastructure that are highly exposed to coastal erosion, storm surges and pluvial flooding (Glavovic et al., Reference Glavovic, Dawson, Chow, Garschagen, Haasnoot, Singh, Thomas, Pörtner, Roberts, Tignor and Rama2022). Human security dimensions here deal, for example, with climate-related hazards and extreme events on coastal energy, transport and water infrastructures, as well as the associated effects on social infrastructures and systems, which are highly interconnected (Pal et al., Reference Pal, Kumar and Mukhopadhyay2023). While current research still focuses on physical infrastructure (Huddleston et al., Reference Huddleston, Smith, White and Elrick-Barr2022), there is an increasing understanding of the importance of analysing human security impacts through cascading events, including direct and indirect effects on social systems (Barquet et al., Reference Barquet, Englund, Inga, André and Segnestam2023) and compound risks that result from the combination of multiple climate hazards and interplay with anthropogenic drivers of coastal exposure and vulnerability (Cutter, Reference Cutter2018; Collins et al., Reference Collins, Sutherland, Bouwer, Cheong, Frolicher, Jacot Des Combes, Koll Roxy, Losada, McInnes, Ratter, Rivera-Arriaga, Susanto, Swingedouw, Tibig, Pörtner, Roberts, Masson-Delmotte and Weyer2019).

Water, food and fisheries

The nexus of water, food and human security is sensitive to environmental and climate change, including saltwater penetration by sea level rise, storms, floods and subsidence by groundwater loss. Risks to coastal ecosystem services affect freshwater provision, storage and regulation; groundwater flows; aquifer recharge and wetland flooding (Hérivaux et al., Reference Hérivaux, Rey-Valette, Rulleau, Agenais, Grisel, Kuhfuss, Maton and Vinchon2018).

Coastal waters can be overloaded with terrestrial nutrients and chemical, biological and physical pollutants, toxins and pathogens (Cooley et al., Reference Cooley, Schoeman, Bopp, Boyd, Donner, Ito, Kiessling, Martinetto, Ojea, Racault, Rost, Skern-Mauritze, Ghebrehiwet, Pörtner, Roberts, Tignor and Rama2022). While the salinities of many estuaries, deltas, aquifers and soils are increasing, decreasing water quality is endangering human health, agricultural yields (Rakib et al., Reference Rakib, Sasaki, Matsuda, Quraishi, Mahmud, Bodrud-Doza, Ullah, Fatema, Newaz and Bhuiyan2020; Mastrocicco and Colombani, Reference Mastrocicco and Colombani2021) and drinking water availability (Sithara et al., Reference Sithara, Pramada and Thampi2020; Wang and Hong, Reference Wang and Hong2021) which depend heavily on regional variations in environment and human behaviour (Paldor and Michael, Reference Paldor and Michael2021). Water security is also threatened by various direct anthropogenic interventions that degrade coastal ecosystems, such as cutting mangroves, overexploitation of groundwater and pollution, resulting in poverty, tensions and instability (Babuna et al., Reference Babuna, Yang, Tulcan, Dehui, Takase, Guba, Han, Awudi and Li2023). With climate change, coastal water security is becoming intractable, requiring empowerment to avoid vicious circles (Powell et al., Reference Powell, Kløcker Larsen, De Bruin, Powell and Elrick-Barr2017).

Climate and environmental stress reduce coastal food security through decreasing crops, livestock and fishery, soil fertility and agricultural productivity, cultivable land and safe water, affecting livelihoods, especially for marginalised smallholder farmers (Shams and Shohel, Reference Shams and Shohel2016) with low investments in resilient infrastructure (Ismail et al., Reference Ismail, Singh, Sarangi, Srivastava, Bhowmick, Lama, Burman, Mandal, Sarangi and Sen2022). Regional studies show the effect of land fragmentation on farm efficiency and diversification in household food security in Vietnam (Tran and Van Vu, Reference Tran and Van Vu2021) and climate challenges on Arctic food security, weakening food sovereignty and destabilising indigenous practices (Zimmermann et al., Reference Zimmermann, Dermody, Theunissen, Wassen, Divine, Padula, von Wehrden and Dorresteijn2023). Coastal households of Bangladesh had a significantly lower Food Consumption Score than other areas (Rahman et al., Reference Rahman, Zulfiqar, Ullah, Himanshu and Datta2023). Perceptions of small-scale fishers in Bangladesh show that wellbeing is more associated with fish yield than climatic stress (Alam and Mallick, Reference Alam and Mallick2022).

Linking ocean and land food supply chains across coasts, marine fisheries and aquaculture provide a significant fraction of human animal protein (Costello et al., Reference Costello, Cao, Gelcich, Cisneros-Mata, Free, Froehlich, Golden, Ishimura, Maier, Macadam-Somer, Mangin, Melnychuk, Miyahara, de Moor, Naylor, Nøstbakken, Ojea, O’Reilly, Parma, Plantinga, Thilsted and Lubchenco2020), dietary micronutrients (Vianna et al., Reference Vianna, Zeller and Pauly2020), livelihoods and income (Harper et al., Reference Harper, Adshade, Lam, Pauly and Sumaila2020), in particular in Small Island Developing States and Indigenous Peoples (Cisneros-Montemayor et al., Reference Cisneros-Montemayor, Pauly, Weatherdon and Ota2016). Temperature is a major driver of fishery changes, with other factors like acidification, deoxygenation and sea ice loss, placing many fisheries at risk of collapse, affecting fishery biomass, food web, catch and value (Olsen et al., Reference Olsen, Kaplan, Ainsworth, Fay, Gaichas, Gamble, Girardin, Eide, Ihde, Morzaria-Luna, Johnson, Savina-Rolland, Townsend, Weijerman, Fulton and Link2018). Declining fish stocks are expected to have detrimental effects on marine life, ecosystems and services, harming dependent human communities, including Arctic Indigenous Peoples (Steiner et al., Reference Steiner, Cheung, Cisneros-Montemayor, Drost, Hayashida, Hoover, Lam, Sou, Sumaila, Suprenand, Tai and VanderZwaag2019). Global warming drives ocean and coastal fauna towards higher latitudes, challenging fishers to change habits and management (Smith et al., Reference Smith, Dowling and Brown2019).

Human wellbeing and health

Health security is closely linked to climate-related disasters and impacts on water, food and fishing. On the one hand, physical health concerns in coastal regions refer to malnutrition due to climate-related impacts, such as ocean warming and acidification, on fisheries, as well as direct and indirect health impacts from ocean warming, sea level rise and storm surges, including injuries and increasing exposure to waterborne diseases (Weatherdon et al., Reference Weatherdon, Magnan, Rogers, Sumaila and Cheung2016; Banwell et al., Reference Banwell, Rutherford, Mackey, Street and Chu2018; Bindoff et al., Reference Bindoff, Cheung, Kairo, Aristegui, Guinder, Hallberg, Hilmi, Jiao, Karim, Levin, O’Donoghue, Purca Cuicapusa, Rinkevich, Suga, Tagliabue, Williamson, Pörtner, Roberts, Masson-Delmotte and Weyer2019; Pugatch, Reference Pugatch2019). On the other hand, there is increasing evidence and research attention to mental health impacts on coastal communities due to increased stress caused by climate-related hazards and pressure to adapt, as well as loss of local livelihoods and cultural heritage due to the impacts of climate change (i.e., ecological grief, solastalgia) (Cunsolo and Ellis, Reference Cunsolo and Ellis2018; Kelman et al., Reference Kelman, Ayeb-Karlsson, Rose-Clarke, Prost, Ronneberg, Wheeler and Watts2021; Phillips and Murphy, Reference Phillips and Murphy2021). Such impacts are especially critical and documented in indigenous coastal communities with strong ties to their local environment (Donatuto et al., Reference Donatuto, Grossman, Konovsky, Grossman and Campbell2014; Ford et al., Reference Ford, Willox, Chatwood, Furgal, Harper, Mauro and Pearce2014).

Human mobility and displacement

Several types of human mobility in coastal zones are related to climate change impacts, especially sea level rise, such as migration, displacement, relocation, retreat or resettlement (Oppenheimer et al., Reference Oppenheimer, Glavovic, Hinkel, Van de Wal, Magnan, Abd-Elgawad, Cai, Cifuentes-Jara, Ghosh, DeConto, Hay, Isla, Marzeion, Meyssignac, Sebesvari, Pörtner, Roberts, Masson-Delmotte and Rama2019). Migration towards coasts can be a driver of vulnerability and exposure, especially in urban areas (Reimann et al., Reference Reimann, Vafeidis and Honsel2023b, Reference Reimann, Jones, Bieker, Wolff, Aerts and Vafeidis2023a), where it increases population numbers and densities and often also includes people with higher vulnerability, such as migrant workers without social security (Hari et al., Reference Hari, Dharmasthala, Koppa, Karmakar and Kumar2021). Migration away from the coast due to climate change impacts has been discussed prominently and controversially in the context of displacement and climate refugees (Boas et al., Reference Boas, Farbotko, Adams, Sterly, Bush, van der Geest, Wiegel, Ashraf, Baldwin, Bettini, Blondin, de Bruijn, Durand-Delacre, Fröhlich, Gioli, Guaita, Hut, Jarawura, Lamers, Lietaer, Nash, Piguet, Rothe, Sakdapolrak, Smith, Tripathy Furlong, Turhan, Warner, Zickgraf, Black and Hulme2019; Lincke and Hinkel, Reference Lincke and Hinkel2021; Farbotko and Campbell, Reference Farbotko and Campbell2022). Planned relocation in the form of resettlement programmes or managed retreat is a type of adaptation, especially to sea level rise (Ferris and Weerasinghe, Reference Ferris and Weerasinghe2020). However, there is uncertainty regarding the precise number of people exposed to increasing sea level as well as its implications for potential climate-related migration. On the one hand, there are several model-based studies with a wide range of assumed population numbers exposed to inundation related to different sea level rise and population projections, but without considering potential adaptation (Hauer et al., Reference Hauer, Fussell, Mueller, Burkett, Call, Abel, McLeman and Wrathall2019; McMichael et al., Reference McMichael, Dasgupta, Ayeb-Karlsson and Kelman2020). On the other hand, studies including assumptions on coastal protection and autonomous adaptation as well as evidence from local case studies demonstrate that exposed populations may have rather higher threshold for out-migration (Esteban et al., Reference Esteban, Takagi, Jamero, Chadwick, Avelino, Mikami, Fatma, Yamamoto, Thao, Onuki, Woodbury, Valenzuela, Crichton and Shibayama2020; Bachner et al., Reference Bachner, Lincke and Hinkel2022).

Besides the potential to reduce risks, all these forms of human mobility can have significant human security impacts since they may involve losses of livelihoods, homes, place attachment, identities, social networks and the potential for conflict between individuals and communities (Black et al., Reference Black, Arnell, Adger, Thomas and Geddes2013). Hence, they are discussed from an environmental justice perspective (Siders, Reference Siders2019; Ajibade et al., Reference Ajibade, Sullivan and Haeffner2020) but also as necessary responses and opportunities in the face of projected climate change impacts in coastal areas (Haasnoot et al., Reference Haasnoot, Lawrence and Magnan2021; Bower et al., Reference Bower, Badamikar, Wong-Parodi and Field2023). At the same time, immobility is increasingly discussed, that is, people or communities who cannot or do not want to move despite climate change impacts (Farbotko et al., Reference Farbotko, Dun, Thornton, McNamara and McMichael2020; McMichael et al., Reference McMichael, Schwerdtle and Ayeb-Karlsson2023).

Societal stability and conflict

There are many conflicts in coastal regions (Dahlet et al., Reference Dahlet, Selim and Van Putten2023), from war and civil war to tensions over the impacts and consequences of weather extremes or disputes over coastal protection and who pays. Populated coastal regions are particularly sensitive to conflict and multiple environmental hazards (Stepanova and Bruckmeier, Reference Stepanova and Bruckmeier2013). Climate-conflict links may affect human security, where climate change is a driver of conflict risk, while conflict can drive climate risk (Mach et al., Reference Mach, Adger, Buhaug, Burke, Fearon, Field, Hendrix, Kraan, Maystadt, O’Loughlin, Roessler, Scheffran, Schultz and von Uexkull2020; Scheffran, Reference Scheffran and Kurtz2022). Coastal storms, floods and sea level rise can undermine the conditions for stability and peace in vulnerable and fragile populations. At the same time, conflict can weaken protective and adaptive capacities against climate impacts. Combined effects of conflict and climate change can destroy dams and dikes and undermine aid and cooperative arrangements for climate protection. Multiple compound risks can trigger a vicious circle of mutually enforcing crises (Buhaug and Von Uexkull, Reference Buhaug and Von Uexkull2021).

Inland and coastal climate-conflict risks can be connected, for example, when people move to the coast where they participate in violent conflict, end up in urban slums or are exposed to coastal risks. Failure to secure the lives and assets of coastal populations can lead to social disruption, tension, instability and displacement. Coastal infrastructures are vulnerable to both climate and conflict impacts, including energy systems and military facilities (Howland, Reference Howland2022). Other forms of coastal conflict involve interest groups, notably those threatening or conserving marine ecology and biodiversity. In the world’s “oceans of conflict” (Nyman, Reference Nyman2013), climate change is one of multiple stressors in fishery conflict, particularly in the North-East Atlantic, East China Sea, West African coast and the Arctic (Spijkers et al., Reference Spijkers, Merrie, Wabnitz, Osborne, Mobjörk, Bodin, Selig, le Billon, Hendrix, Singh, Keys and Morrison2021).

Coastal hotspots

Islands

The literature on human security concerns on small islands often focuses on questions of habitability of low-lying islands due to sea level rise (Farbotko, Reference Farbotko2010; Kelman, Reference Kelman2018; Spencer et al., Reference Spencer, Magnan, Donner, Garschagen, Ford, Duvat and Wabnitz2024). While there is increasing evidence that large shares of island populations will be faced with inundations by 2050 (Mycoo et al., Reference Mycoo, Wairiu, Campbell, Duvat, Golbuu, Maharaj, Nalau, Nunn, Pinnegar, Warrick, Pörtner, Roberts, Tignor and Rama2022), there are also studies demonstrating how reef islands can adjust to sea level change, offering alternative opportunities of adaptation beyond relocation (Masselink et al., Reference Masselink, Beetham and Kench2020; Kench et al., Reference Kench, Liang, Ford, Owen, Aslam, Ryan, Turner, Beetham, Dickson, Stephenson, Vila-Concejo and McLean2023). Moreover, the question of what such evidence, together with other observed climate impacts, means for habitability remains debated due to multiple and diverging perspectives on when experiences of inundation become unbearable (Moftakhari et al., Reference Moftakhari, AghaKouchak, Sanders, Allaire and Matthew2018; Spencer et al., Reference Spencer, Magnan, Donner, Garschagen, Ford, Duvat and Wabnitz2024) or an island becomes effectively uninhabitable (Farbotko and Campbell, Reference Farbotko and Campbell2022). Besides potential inundation due to sea level rise, also the other dimensions of human security are highly relevant and with increasing evidence in the scientific literature, especially regarding Small Island Developing States (SIDS), but also other island geographies (Petzold and Magnan, Reference Petzold and Magnan2019; Duvat et al., Reference Duvat, Magnan, Perry, Spencer, Bell, Wabnitz, Webb, White, McInnes, Gattuso, Graham, Nunn and le Cozannet2021; Mycoo et al., Reference Mycoo, Wairiu, Campbell, Duvat, Golbuu, Maharaj, Nalau, Nunn, Pinnegar, Warrick, Pörtner, Roberts, Tignor and Rama2022; Ortiz et al., Reference Ortiz, Jamero, Crespin, Smith Ramirez, Matias, Reyes, Pauchard and la Viña2023b).

Especially in low-lying atoll or barrier islands, basically all housing and infrastructure are located on or close to the coast. In these cases, hurricanes or tropical cyclones can devastate whole islands and their infrastructure. The island of Barbuda, for example, was devastated and had to be evacuated entirely after Hurricane Irma in 2017 (Burn et al., Reference Burn, Boger, Holmes, Bain, Perdikaris and Boger2022). Apart from extreme events and impacts on critical infrastructure, there is a strong focus in the literature on climate-related impacts on the tourism sector since they make up a significant share of many economies of SIDS and other island types (Posen et al., Reference Posen, Beraud, Harper Jones, Tyllianakis, Joseph-Witzig and St. Louis2023). Depending on the island context and the specific kind of tourism, slow-onset hazards, such as sea level rise, ocean warming, or shifting seasons, as well as fast onset events, such as flooding, can affect individual tourism activities, sites and periods as well as whole tourism economics (Wolf et al., Reference Wolf, Filho, Singh, Scherle, Reiser, Telesford, Miljković, Havea, Li, Surroop and Kovaleva2021; Carrillo et al., Reference Carrillo, González, Pérez, Expósito and Díaz2022).

Food and water insecurity on small islands result from cyclones, droughts, saline intrusion and ocean warming that directly impact agriculture and fisheries. Food security is threatened, especially by the observed decline in fisheries, which affects the main diet in many small island communities (Mycoo et al., Reference Mycoo, Wairiu, Campbell, Duvat, Golbuu, Maharaj, Nalau, Nunn, Pinnegar, Warrick, Pörtner, Roberts, Tignor and Rama2022). Hence, climate change impacts island communities’ ability to produce, import or purchase food (Barnett, Reference Barnett, Connell and Lowitt2020). Accordingly, there is increasing attention to the social dimensions of food security in small islands, with poor population groups particularly affected (Lincoln Lenderking et al., Reference Lincoln Lenderking, Robinson and Carlson2021).

Climate impact on the wellbeing of island communities is closely linked to food insecurity due to potential undernutrition. Other prominent health impacts result from the increasing and shifting range of vector-borne diseases (Thomas et al., Reference Thomas, Baptiste, Martyr-Koller, Pringle and Rhiney2020). Relatively little but increasing attention in the literature is being paid to mental health impacts on islands, for example, anxiety and stress due to changing weather patterns and depression due to the inability to adapt livelihoods to climate-induced environmental changes and degradation (Kelman et al., Reference Kelman, Ayeb-Karlsson, Rose-Clarke, Prost, Ronneberg, Wheeler and Watts2021). Related concepts that are gaining prominence and with relevance to islands are those around non-economic loss and damage (Thomas and Benjamin, Reference Thomas and Benjamin2020; McNamara et al., Reference McNamara, Westoby, Clissold and Chandra2021), ecological grief (Cunsolo and Ellis, Reference Cunsolo and Ellis2018) and solastalgia (McNamara and Westoby, Reference McNamara and Westoby2011) due to climate change-induced degradation and loss of habitats and landscapes. Going beyond the traditional concept of health, there are attempts to widen our understanding of wellbeing, which is especially important for climate-affected indigenous communities such as those on Pacific islands, who consider, for example, people-place connections and traditional knowledge systems central parts of wellbeing (Sterling et al., Reference Sterling, Pascua, Sigouin, Gazit, Mandle, Betley, Aini, Albert, Caillon, Caselle, Cheng, Claudet, Dacks, Darling, Filardi, Jupiter, Mawyer, Mejia, Morishige, Nainoca, Parks, Tanguay, Ticktin, Vave, Wase, Wongbusarakum and McCarter2020).

Human mobility in the context of climate change has different dimensions and human security implications on small islands. In many island and archipelagic communities, such as in the Pacific, migration is part of people’s livelihood strategy and, therefore, an important aspect contributing to the security of these populations (Connell, Reference Connell2016). On the other hand, forced displacement or migration due to climate risk is considered a last resort, if at all (Thomas et al., Reference Thomas, Baptiste, Martyr-Koller, Pringle and Rhiney2020; Piggott-McKellar and McMichael, Reference Piggott-McKellar and McMichael2021). Nonetheless, due to the potential loss of habitability of islands due to climate impacts, relocation of communities is increasingly discussed as necessary and important part of risk reduction in response to climate change (Magnan et al., Reference Magnan, Oppenheimer, Garschagen, Buchanan, Duvat, Forbes, Ford, Lambert, Petzold, Renaud, Sebesvari, van de Wal, Hinkel and Pörtner2022). Human security concerns around climate-induced migration, displacement or retreat on small islands relate to the resulting loss of place attachment, livelihoods, financial resources, community cohesion and social networks (Dannenberg et al., Reference Dannenberg, Frumkin, Hess and Ebi2019). Moreover, climate-induced migration and relocation can lead to conflicts between migrants and host communities and within migrant communities, for example, due to power struggles, ethnical conflicts and competition for land (Donner, Reference Donner2015). However, there is little evidence for such conflicts (Weir and Virani, Reference Weir and Virani2011; Kelman, Reference Kelman2015).

Coastal settlements and megacities

A great deal of literature on climate change impacts on coastal settlements deals with coastal megacities and impacts on critical urban infrastructure and livelihoods (Pelling and Blackburn, Reference Pelling and Blackburn2013). Many of the most vulnerable coastal cities lie in the tropics, including megacities such as Mumbai and Guangzhou and other major agglomerations such as Abidjan or Guayaquil (Hallegatte et al., Reference Hallegatte, Green, Nicholls and Corfee-Morlot2013). Impacts on critical infrastructure such as roads and harbours do not only directly affect cities and their populations but also trade networks and supply chains and are therefore felt far beyond the city context (Glavovic et al., Reference Glavovic, Dawson, Chow, Garschagen, Haasnoot, Singh, Thomas, Pörtner, Roberts, Tignor and Rama2022). Most affected by environmental pressures and hazards related to climate change in urban areas are low-income populations in the Global South (Adelekan et al., Reference Adelekan, Cartwright, Chow, Colenbrander, Dawson, Garschagen, Haasnoot, Hashizume, Klaus, Krishnaswamy, Fernanda Lemos, Ley, McPhearson, Pelling, Portner, Revi, Sara, Simpson, Singh, Solecki, Thomas and Trisos2022) and underprivileged ethnicities (Gran Castro and Ramos De Robles, Reference Gran Castro and Ramos De Robles2019) who suffer from social or ethnic exclusion, low-quality or non‑existent infrastructure, little tenure security and restricted access to resources and services.

The literature on food insecurity due to climate change focuses rather on rural or smaller coastal settlements than on megacities, with a higher degree of resource-dependent and subsistence populations, for example, in coastal Bangladesh, where increased salinity impacts the agricultural harvests and fisheries (Hanazaki et al., Reference Hanazaki, Berkes, Seixas and Peroni2013; Lam et al., Reference Lam, Winch, Nizame, Broaddus-Shea, Harun and Surkan2022). Nonetheless, especially the fishing sector is still an important economic element in many larger coastal cities, such as Jakarta, on which many livelihoods depend (Padawangi, Reference Padawangi and Holt2012). Water insecurity in coastal cities is caused by a growing demand of increasing urban populations and changing water availability due to climate change (Flörke et al., Reference Flörke, Schneider and McDonald2018). Desalination of sea water as a response to water scarcity in coastal cities may reduce water stress but can negatively impact coastal and marine ecosystems (Roberts et al., Reference Roberts, Johnston and Knott2010).

Health security in coastal cities is affected by extreme events, such as tropical cyclones, hurricanes and flooding. Flooding can result in the spread of waterborne diseases, to which especially populations in informal settlements are vulnerable, who lack adequate flood protection and suffer from insufficient sanitary infrastructure (Dawson et al., Reference Dawson, Khan, Gornitz, Lemos, Atkinson, Pullen, Osorio, Usher, Rosenzweig, Solecki, Romero-Lankao, Mehrotra, Dhakal and Ibrahim2018). In the coastal megacities of Mumbai, for example, a large share of the population lives in slums, which experience inundations regularly due to pluvial flooding (Romero-Lankao et al., Reference Romero-Lankao, Gnatz and Sperling2016). Other coastal cities that suffer from subsidence also experience coastal flooding, with marginalised communities most affected (Nurhidayah and McIlgorm, Reference Nurhidayah and McIlgorm2019; Cao et al., Reference Cao, Esteban, Valenzuela, Onuki, Takagi, Thao and Tsuchiya2021).

Sea level rise is expected to trigger displacement from coastal settlements, differing between geographic and socioeconomic contexts. Forced displacement is expected to be less relevant in larger coastal cities of the Global North (Magnan et al., Reference Magnan, Oppenheimer, Garschagen, Buchanan, Duvat, Forbes, Ford, Lambert, Petzold, Renaud, Sebesvari, van de Wal, Hinkel and Pörtner2022) where high investments are made to protect valuable assets, real estate and infrastructure. Smaller towns and rural areas already deal with managed retreat (Dannenberg et al., Reference Dannenberg, Frumkin, Hess and Ebi2019). Moreover, in several megacities of the Global South, especially the informal settlements face forced evictions due to their vulnerability to flooding, which can result in conflicts and unsustainable outcomes for the affected populations (Ahmed and Meenar, Reference Ahmed and Meenar2018; Ajibade, Reference Ajibade2019). While impacts on mental health are documented mainly in smaller coastal settlements and resource-dependent communities, the stress of worsening urban flood events for low-income communities and potential forced displacement has mental health implications, especially for the poor and marginalised ones (Neria and Shultz, Reference Neria and Shultz2012; Lane et al., Reference Lane, Charles-Guzman, Wheeler, Abid, Graber and Matte2013; Garrett et al., Reference Garrett, Clitherow, White, Wheeler and Fleming2019).

River deltas and estuaries

River delta regions benefit from the combination of abundant water, agriculturally fertile floodplains, ports, economic production and trade, contributing to human wealth and wellbeing. Many of the largest port cities are located in delta formations (Campanella, Reference Campanella2010), and more than 300 million people live in 40 deltas, including all the major megadeltas (Ericson et al., Reference Ericson, Vorosmarty, Dingman, Ward and Meybeck2006). A large number of people live in the river deltas of the Ganges-Brahmaputra, Pearl River and Nile. Populations face human security risks when river deltas and estuaries are vulnerable to the combined effects of climate change and intensive human use, both from the land and ocean sides, which interact in complex ways (Nicholls et al., Reference Nicholls, Adger, Hutton and Hanson2020). The ecological sensitivity in transition zones makes them predestined to become hot spots for climate change impacts. Physical variables (temperature, salinity, flow direction and velocity) and societal parameters (e.g., resource use, sediment input or removal, water quality impairment and sediment discharge) interact with secondary effects in delta regions of flooding, water shortages or droughts.

Rising sea levels in river deltas can lead to flooding, subsidence, saltwater intrusion, loss of coastal wetlands or declining quality of agricultural land. Since the beginning of the 21st century, 85% of the world’s largest river deltas have experienced severe flooding, at least temporarily submerging some 260,000 km2 of land area (Syvitski et al., Reference Syvitski, Kettner, Overeem, Hutton, Hannon, Brakenridge, Day, Vörösmarty, Saito, Giosan and Nicholls2009). Considering the predicted changes in rainfall variability, extreme weather events and rising sea levels, highly vulnerable areas in coastal or deltaic regions will be increasingly challenged (Tessler et al., Reference Tessler, Vörösmarty, Grossberg, Gladkova, Aizenman, Syvitski and Foufoula-Georgiou2015) by large‑scale damages and loss of life (Brondizio et al., Reference Brondizio, Vogt, Mansur, Anthony, Costa and Hetrick2016). Climate-related hazards affect exposed infrastructures and resources and, in the long term, may lead to societal impacts on life and health, eventually resulting in migration, resettlement and displacement from delta regions. Cities in urban deltas of developing countries face compounding effects of high exposure and low adaptive capacities (Bangalore et al., Reference Bangalore, Smith and Veldkamp2019). In many delta regions, the most affected are the urban poor, for instance, the Black poor during Hurricane Katrina 2005 (Kates et al., Reference Kates, Colten, Laska and Leatherman2006) or informal settlers in the 2015 flood in the Jacuí River delta (Pereira Santos et al., Reference Pereira Santos, Rodriguez-Lopez, Chiarel and Scheffran2022).

These challenges affect all major river deltas, to different degrees depending on geographic location (Scheffran and Link, Reference Scheffran, Link, Lozan, Breckle, Grassl, Kuttler and Matzarakis2019). The most vulnerable urban deltas in 2050, measured as a share of gross domestic product (GDP) losses, would be Guangzhou, Mumbai, Kolkata, Guayaquil, Shenzen, Miami, Tianjin, New York, Ho Chi Minh City and New Orleans (Ovink, Reference Ovink2015). Without fundamental changes, about 2 billion people could be affected by 2050 and 4 billion by 2080. Key problem factors in selected river deltas are spatial pressure, flood vulnerability, drinking water shortages, ageing or inadequate infrastructure, coastal erosion and loss of environmental quality and biodiversity (Ovink, Reference Ovink2015).

While the Mediterranean Basin is largely rocky, river deltas face increased erosion patterns, decreased sediment discharge, intensification of floods, saltwater intrusion and loss of biodiversity, multiplied by climate change. Besides the Italian Po Delta, these issues concern the Spanish Ebro Delta, where human management has had a higher impact than climate change (Fatorić and Chelleri, Reference Fatorić and Chelleri2012). The heavy urban use of Nile water in the Cairo region also has a negative impact on water quality in the delta. Therefore, (mostly fossil) groundwater is regularly used to irrigate agricultural land. This results in saltwater inflows into groundwater or land subsidence when groundwater aquifers are drained (Mabrouk et al., Reference Mabrouk, Jonoski, H. P. Oude Essink and Uhlenbrook2018), increasing the relative effect of rising sea levels. The Nile Delta cannot be easily protected by hard coastal protection measures (Link et al., Reference Link, Kominek and Scheffran2013; Mabrouk et al., Reference Mabrouk, Jonoski, H. P. Oude Essink and Uhlenbrook2018).

The Pearl River Delta (PRD) is sensitive and variable due to the strong monsoon, dense river network and significant effects of erosion and sedimentation. The combination of rapid economic development, population growth and climate change makes the PRD vulnerable to flooding and other disasters (Yang et al., Reference Yang, Scheffran, Qin and You2015). Even small-scale sea level rise increases storm surge risk and post-storm reconstruction costs. Damage is high in low-lying urban areas with high levels of prosperity and vital infrastructure. In large cities such as Hong Kong, Shenzhen and Guangzhou, the population is particularly vulnerable to flood hazards.

In other parts of the world, delta vulnerability to climate change also combines with local factors, such as agricultural livelihoods in Bangladesh sensitive to salinity intrusion (Khanom, Reference Khanom2016), or civil conflict and violent skirmishes between herders and farmers in Kenya’s Tana River Delta (Kirchner, Reference Kirchner2013).

Coastal adaptation

Coastal governance

Overall, there is increasing evidence of adaptation in coastal areas around the globe, especially in urban areas, which, however, is still far behind the adaptation potential and need, and lacking of long-term pathways approaches based on early warning and anticipative governance (Magnan et al., Reference Magnan, Bell, Duvat, Ford, Garschagen, Haasnoot, Lacambra, Losada, Mach, Noblet, Parthasaranthy, Sano, Vincent, Anisimov, Hanson, Malmström, Nicholls and Winter2023a). Political ecology approaches in coastal governance include issues of power and politics, knowledge and narratives, scale and history, justice and fairness (Zou et al., Reference Zou, Zhang, Lee and Tsai2023). Facing human security risks in coastal regions, effective and integrative governance is needed to shape coastal futures through institutions, norms, rules, laws and procedures that manage, implement and monitor policies at local to global scales. Governance can be adaptive to maintain a desired state under changing conditions, polycentric with multiple decision-making bodies and multi-level, including local to global scales (Jordan et al., Reference Jordan, Huitema, Van Asselt and Forster2018; Carlisle and Gruby, Reference Carlisle and Gruby2019). Multi-level governance, coordination and knowledge co-production across societal actors are required also for more transformational adaptation (Ratter and Leyshon, Reference Ratter, Leyshon and Storch2021; Rölfer et al., Reference Rölfer, Celliers and Abson2022; Niamir and Pachauri, Reference Niamir and Pachauri2023), although there is limited evidence of implemented governance concepts for transformational coastal adaptation (Bouwer et al., Reference Bouwer, Cheong, Jacot Des Combes, Frölicher, McInnes, Ratter and Rivera-Arriaga2022).

Climate and ocean governance can use the power of governments, nature and communities utilising different forms of governance capacity that need to be coordinated to resolve conflicts (Kullenberg, Reference Kullenberg2010). For example, in terms of coastal critical infrastructure, this implies building early warning systems and adaptive capacity across different levels of organisation, especially where it comes to the task of effectively implementing local adaptation actions (Huddleston et al., Reference Huddleston, Smith, White and Elrick-Barr2023). However, the current academic evidence base is strongly biased towards assessing risk, planning and monitoring rather than implementing coastal adaptation, and lacks an integration of existing coastal management and governance instruments with climate change adaptation frameworks (Cabana et al., Reference Cabana, Rölfer, Evadzi and Celliers2023). A synthesis to understand and manage cross-sectoral governance conflicts highlights conceptual differences and commonalities across disciplines to develop problem-solving frameworks of coastal and marine governance, including ecosystem-based management, adaptive co-management, integrated management, collaborative governance and marine spatial planning, and others (Bellanger et al., Reference Bellanger, Speir, Blanchard, Brooks, Butler, Crosson, Fonner, Gourguet, Holland, Kuikka, le Gallic, Lent, Libecap, Lipton, Nayak, Reid, Scemama, Stephenson, Thébaud and Young2020).

Coastal management and protection

Coastal protection against human security risks of climate change is a societal task that relies on government measures and resources to prevent coastline retreat and defend settlements and infrastructure at the shore and hinterland from storm- or sea level-related flooding and erosion. Engineering-based hard structures (such as breakwaters, dikes or seawalls) (Sorensen, Reference Sorensen2006) are complemented by soft measures embedded into social and ecological systems, involving the participation of stakeholders and social-science perspectives (Magnan et al., Reference Magnan, Oppenheimer, Garschagen, Buchanan, Duvat, Forbes, Ford, Lambert, Petzold, Renaud, Sebesvari, van de Wal, Hinkel and Pörtner2022; Philippenko and Le Cozannet, Reference Philippenko and Le Cozannet2023). These measures are coordinated in coastal management, which increasingly is integrated, ecosystem-based and climate-resilient, including risk assessment, watershed management and catchment rehabilitation, sustainable land and water management, coastline protection, adapted to the specific conditions of coastal cities, islands, deltas and marine habitats (Hinkel et al., Reference Hinkel, Aerts, Brown, Jiménez, Lincke, Nicholls, Scussolini, Sanchez-Arcilla, Vafeidis and Addo2018; Bouwer et al., Reference Bouwer, Cheong, Jacot Des Combes, Frölicher, McInnes, Ratter and Rivera-Arriaga2022; Petzold et al., Reference Petzold, Joe, Kelman, Magnan, Mirbach, Nagle Alverio, Nunn and Ratter2023).

Coastal management strategies group around adapting, defending and armouring a coastal area or abandoning or relocating part of it, depending on benefit, cost and risk assessments (Gopalakrishnan et al., Reference Gopalakrishnan, Landry, Smith and Whitehead2016; Kovalevsky and Scheffran, Reference Kovalevsky and Scheffran2022; NOAA, 2023; Sengupta et al., Reference Sengupta, Kovalevsky, Bouwer and Scheffran2023). Several studies focus on coastal adaptation to climate change and sea level (Bongarts Lebbe et al., Reference Bongarts Lebbe, Rey-Valette, Chaumillon, Camus, Almar, Cazenave, Claudet, Rocle, Meur-Férec, Viard, Mercier, Dupuy, Ménard, Rossel, Mullineaux, Sicre, Zivian, Gaill and Euzen2021; Griggs and Reguero, Reference Griggs and Reguero2021) and the institutional adaptive capacity building of Swedish coastal zone management (Storbjörk and Hedrén, Reference Storbjörk and Hedrén2011), others address path dependency in coastal cities of the Asia-Pacific (Nunn et al., Reference Nunn, Smith and Elrick-Barr2021b) and proactive adaptation of rapidly changing coasts (Brown et al., Reference Brown, Naylor and Quinn2017). Some highlight maladaptation of seawalls along island coasts (Nunn et al., Reference Nunn, Klöck and Duvat2021a) and the diffusion of hard protection to coastal erosion and flooding along island coasts in the Pacific and Indian Oceans (Klöck et al., Reference Klöck, Duvat and Nunn2022). In specific small and low-lying island contexts, also land reclamation and island raising are being implemented (Brown et al., Reference Brown, Nicholls, Bloodworth, Bragg, Clauss, Field, Gibbons, Pladaitė, Szuplewski, Watling, Shareef and Khaleel2023).

The diversity of approaches in coastal areas includes internal relocation as an adaptation strategy in Rangiroa Atoll, French Polynesia (Duvat et al., Reference Duvat, Magnan, Goeldner-Gianella, Grancher, Costa, Maquaire, le Cozannet, Stahl, Volto and Pignon-Mussaud2022) and contestation of coastal restoration and risk reduction in Louisiana (Gotham, Reference Gotham2016). To regulate ocean grabbing, a large-scale marine protected area for the sea of Rapa Nui is suggested by Aburto et al. (Reference Aburto, Gaymer and Govan2020). Economically efficient flood protection standards for the Netherlands are considered by Kind (Reference Kind2014). The contribution of Earth observation in coastal climate services for small islands is discussed by Rölfer et al. (Reference Rölfer, Winter, Máñez Costa and Celliers2020). Coastal adaptation planning can use scenario-based stakeholder engagement and preferences in coastal planning (Tompkins et al., Reference Tompkins, Few and Brown2008), stakeholder perception of climate vulnerability detection using Fuzzy Cognitive Mapping (Gray et al., Reference Gray, Gagnon, Gray, O’Dwyer, O’Mahony, Muir, Devoy, Falaleeva and Gault2014) and stakeholder analysis of climate change and water management in the Dongjiang River basin in South China (Yang et al., Reference Yang, Chan and Scheffran2018).

Nature-based solutions

According to the World Conservation Union (IUCN), nature-based solutions (NbS) are defined as “actions to protect, sustainably manage, and restore natural or modified ecosystems, that address societal challenges effectively and adaptively, simultaneously providing human wellbeing and biodiversity benefits” (Cohen-Shacham et al., Reference Cohen-Shacham, Walters, Janzen and Maginnis2016, p. 5). The IPCC focuses on NbS contributions to climate adaptation and mitigation benefits for coastal regions, including synergies with biodiversity protection and ecosystem services. While the carbon-sequestering mitigation role has dominated much of the earlier discussions, NbS contributions to climate adaptation are increasingly emphasised.

Many studies demonstrate that coastal and marine ecosystems, including wetlands and mangroves, have considerable value as carbon sinks in ‘blue carbon’ sequestration and other ecosystem services such as hydrological regulation, coastal protection, biodiversity and contributing to human livelihoods, especially of pastoralists and fishermen (Conant et al., Reference Conant, Cerri, Osborne and Paustian2017; Leifeld and Menichetti, Reference Leifeld and Menichetti2018; Seddon et al., Reference Seddon, Turner, Berry, Chausson and Girardin2019). Mangrove restoration can promote local and national adaptation, depending on the extent and nature of coastlines (Taillardat et al., Reference Taillardat, Thompson, Garneau, Trottier and Friess2020). The global value of coastal wetlands for storm protection is demonstrated by Costanza et al. (Reference Costanza, Anderson, Sutton, Mulder, Mulder, Kubiszewski, Wang, Liu, Pérez-Maqueo, Luisa Martinez, Jarvis and Dee2021), while Schueler (Reference Schueler2017) presents NbS to enhance coastal resilience, and Landry (Reference Landry2011) discusses coastal erosion as a natural resource management problem from an economic perspective. Challenges of NbS in coastal research for coastal engineers are addressed by Scheres and Schüttrumpf (Reference Scheres, Schüttrumpf, Viet, Xiping and Tung2020) and socioecological impacts of coastal flood mitigation by Inácio et al. (Reference Inácio, Karnauskaitė, Mikša, Gomes, Kalinauskas, Pereira, Ferreira, Kalantari, Hartmann and Pereira2020).

Examples of regional perspectives address flood risk management using NbS in Nouakchott, Mauritania (Senhoury et al., Reference Senhoury, Niang, Diouf, Thomas, Renaud, Sudmeier-Rieux, Estrella and Nehren2016), coastal protection on the Islands of Amrum and Föhr in the North Frisian Wadden Sea (Jordan et al., Reference Jordan, Döring, Fröhle and Ratter2023), and ecosystem-based urban climate change adaptation and wellbeing in Kiribati, Samoa and Vanuatu (Kiddle et al., Reference Kiddle, Bakineti, Latai-Niusulu, Missack, Pedersen Zari, Kiddle, Chanse, Blaschke and Loubser2021). Capacity building on ecosystem-based adaptation helps to cope with extreme events and sea level rise. It increases coastal resilience to extreme weather events and sea level rise on the Uruguayan coast (Carro et al., Reference Carro, Seijo, Nagy, Lagos and Gutiérrez2018). Here, a participatory process involved the community and institutional stakeholders in selecting and prioritising adaptation measures, including soft measures (green infrastructure) such as revegetation with native species, dune regeneration, sustainable drainage systems and reducing use pressures.

Community-based adaptation

Adaptation to climate risk can also build on and promote community resilience. For example, many coastal and small island communities are place-based communities – that is, depending on the local environment to secure their livelihoods – and have traditional and local knowledge that makes them adaptable to environmental changes (Kelman, Reference Kelman2010; Hiwasaki et al., Reference Hiwasaki, Luna and Marçal2015). Dense social networks and strong place attachment in such communities may also contribute to their adaptability to environmental change (Petzold and Ratter, Reference Petzold and Ratter2015; Carmen et al., Reference Carmen, Fazey, Ross, Bedinger, Smith, Prager, McClymont and Morrison2022). Accordingly, there is a move from top-down approaches to community-based adaptation (CbA) approaches, for example, in SIDS (McNamara et al., Reference McNamara, Clissold, Westoby, Piggott-McKellar, Kumar, Clarke, Namoumou, Areki, Joseph, Warrick and Nunn2020).

Examples of CbA in coastal areas are collective coastal afforestation in Bangladesh (Rawlani and Sovacool, Reference Rawlani and Sovacool2011) or communal water resource management, agricultural management and disaster risk community action plans in Vanuatu (Clarke et al., Reference Clarke, McNamara, Clissold and Nunn2019). However, besides the suggested advantages of CbA as a locally led and context-specific form of adaptation, there have always been concerns in the literature regarding responsibilities and representation, effectiveness regarding larger-scale issues, and barriers to long-term success (Forsyth, Reference Forsyth2013; Piggott-McKellar et al., Reference Piggott-McKellar, McNamara, Nunn and Watson2019; Westoby et al., Reference Westoby, McNamara, Kumar and Nunn2020).

Conclusions

The human security lens addresses the interactions, multifaceted impacts and systemic risks to the vital core of human lives in different coastal contexts, such as islands, deltas and coastal megacities. Coastal regions and their growing populations are exposed to multiple local environmental and global climate hazards, threatening human life, health and infrastructures, water, food and fisheries, driving displacement and relocation to and away from the coast, as well as various forms of conflict interacting with social vulnerability. Climate change acts as a threat multiplier in interconnected vulnerable infrastructures, linkages between water and food, mobility and conflict, resulting in vicious circles of compounding and cascading impacts with severe risks to societal stability and novel challenges to coastal governance regimes. Vulnerability and adaptation of fishery, agriculture and aquaculture interact along coasts, connecting land, sea and rivers.

While the potential consequences of climate change in coastal areas are severe, they can be prevented by appropriate governance mechanisms which contain human security risks before they overwhelm the limits of adaptation (Dow et al., Reference Dow, Berkhout and Preston2013; Thomas et al., Reference Thomas, Theokritoff, Lesnikowski, Reckien, Jagannathan, Cremades, Campbell, Joe, Sitati, Singh, Segnon, Pentz, Musah-Surugu, Mullin, Mach, Gichuki, Galappaththi, Chalastani, Ajibade, Ruiz-Diaz, Grady, Garschagen, Ford and Bowen2021). An integrative human security perspective focusing on protecting freedom and capacity to live with dignity can contribute to identifying whether incremental adaptation or rather transformational measures are required with respect to observed and projected climate change impacts. Anticipatory and transformational governance approaches would rely on early warning, model-based simulation and preventive policies, which are more promising and less costly than disaster and crisis management. Besides hard and soft coastal management interventions, integrative approaches of climate resilience and transformational adaptation across multiple scales can build on NbS and CbA adequate to the respective geographical coastal environments. To avoid maladaptation and combined human security risks that reduce local resilience, coastal management and adaptation must not only tackle individual concerns but adopt a holistic human security approach. To this end, human security research needs to understand trade-offs and synergies in the growing body of research, for example, on mental health, urban–rural interactions, movements and sustainable transformations of coastal settlements that strengthen human security, especially of marginalised coastal communities.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/cft.2024.2.

Data availability statement

Data availability is not applicable to this article as no new data were created or analysed in this study.

Acknowledgements

The authors would like to thank the editor and reviewers for their constructive feedback on earlier versions of this paper.

Author contribution

Both authors contributed equally to the development and writing of the manuscript.

Financial support

This work was supported by the following funding grants: Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany’s Excellence Strategy - EXC 2037 ‘CLICCS – Climate, Climatic Change, and Society’ – Project Number: 390683824, contribution to the Center for Earth System Research and Sustainability (CEN) of Universität Hamburg (J.S.) and German Federal Ministry of Education and Research (BMBF; Grant No. 01LN1710A1) (J.P.).

Competing interest

The authors declare no competing interests.

References

Aburto, JA, Gaymer, CF and Govan, H (2020) A large-scale marine protected area for the sea of Rapa Nui: From ocean grabbing to legitimacy. Ocean & Coastal Management 198, 105327. https://doi.org/10.1016/j.ocecoaman.2020.105327.CrossRefGoogle Scholar
Adelekan, I, Cartwright, A, Chow, W, Colenbrander, S, Dawson, R, Garschagen, M, Haasnoot, M, Hashizume, M, Klaus, I, Krishnaswamy, J, Fernanda Lemos, M, Ley, D, McPhearson, T, Pelling, M, Portner, H-O, Revi, A, Sara, ML, Simpson, NP, Singh, C, Solecki, W, Thomas, A and Trisos, C (2022) Climate Change in Cities and Urban Areas: Impacts, Adaptation and Vulnerability. Indian Institute for Human Settlements. Available at https://iihs.co.in/knowledge-gateway/climate-change-in-cities-and-urban-areas-impacts-adaptation-and-vulnerability/ (accessed 26 February 2024).Google Scholar
Adger, WN, Pulhin, JM, Barnett, J, Dabelko, GD, Hovelsrud, GK, Levy, M, Oswald Spring, U and Vogel, CH (2014) Human security. In Field, CB, Barros, VR, Dokken, DJ and White, LL (eds), Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, pp. 755791.Google Scholar
Ahmed, S and Meenar, M (2018) Just sustainability in the global south: A case study of the megacity of Dhaka. Journal of Developing Societies 34(4), 401424. https://doi.org/10.1177/0169796X18806740.CrossRefGoogle Scholar
Ajibade, I (2019) Planned retreat in global south megacities: Disentangling policy, practice, and environmental justice. Climatic Change 157(2), 299317. https://doi.org/10.1007/s10584-019-02535-1.CrossRefGoogle Scholar
Ajibade, I, Sullivan, M and Haeffner, M (2020) Why climate migration is not managed retreat: Six justifications. Global Environmental Change 65, 102187. https://doi.org/10.1016/j.gloenvcha.2020.102187.CrossRefGoogle Scholar
Alam, E and Mallick, B (2022) Climate change perceptions, impacts and adaptation practices of fishers in Southeast Bangladesh coast. International Journal of Climate Change Strategies and Management 14(2), 191211. https://doi.org/10.1108/IJCCSM-02-2021-0019.CrossRefGoogle Scholar
Babuna, P, Yang, X, Tulcan, RXS, Dehui, B, Takase, M, Guba, BY, Han, C, Awudi, DA and Li, M (2023) Modeling water inequality and water security: The role of water governance. Journal of Environmental Management 326, 116815. https://doi.org/10.1016/j.jenvman.2022.116815.CrossRefGoogle ScholarPubMed
Bachner, G, Lincke, D and Hinkel, J (2022) The macroeconomic effects of adapting to high-end sea-level rise via protection and migration. Nature Communications 13(1), 5705. https://doi.org/10.1038/s41467-022-33043-z.CrossRefGoogle ScholarPubMed
Bangalore, M, Smith, A and Veldkamp, T (2019) Exposure to floods, climate change, and poverty in Vietnam. Economics of Disasters and Climate Change 3(1), 7999. https://doi.org/10.1007/s41885-018-0035-4.CrossRefGoogle Scholar
Banwell, N, Rutherford, S, Mackey, B, Street, R and Chu, C (2018) Commonalities between disaster and climate change risks for health: A theoretical framework. International Journal of Environmental Research and Public Health 15(3), 538. https://doi.org/10.3390/ijerph15030538.CrossRefGoogle ScholarPubMed
Barnett, J (2020) Climate change and food security in the Pacific Islands. In Connell, J and Lowitt, K (eds), Food Security in Small Island States. Singapore: Springer Singapore, pp. 2538. https://doi.org/10.1007/978-981-13-8256-7_2.CrossRefGoogle Scholar
Barquet, K, Englund, M, Inga, K, André, K and Segnestam, L (2023) Conceptualising multiple hazards and cascading effects on critical infrastructures. Disasters 48, e12591. https://doi.org/10.1111/disa.12591.Google ScholarPubMed
Bellanger, M, Speir, C, Blanchard, F, Brooks, K, Butler, JRA, Crosson, S, Fonner, R, Gourguet, S, Holland, DS, Kuikka, S, le Gallic, B, Lent, R, Libecap, GD, Lipton, DW, Nayak, PK, Reid, D, Scemama, P, Stephenson, R, Thébaud, O and Young, JC (2020) Addressing marine and coastal governance conflicts at the interface of multiple sectors and jurisdictions. Frontiers in Marine Science 7, 544440. https://doi.org/10.3389/fmars.2020.544440.CrossRefGoogle Scholar
Bindoff, NL, Cheung, WWL, Kairo, JG, Aristegui, J, Guinder, VA, Hallberg, R, Hilmi, N, Jiao, N, Karim, MS, Levin, L, O’Donoghue, S, Purca Cuicapusa, SR, Rinkevich, B, Suga, T, Tagliabue, A and Williamson, P (2019) Changing ocean, marine ecosystems, and dependent communities. In Pörtner, H-O, Roberts, DC, Masson-Delmotte, V and Weyer, NM (eds), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge, UK and New York, NY: Cambridge University Press, pp. 447587.Google Scholar
Black, R, Arnell, NW, Adger, WN, Thomas, D and Geddes, A (2013) Migration, immobility and displacement outcomes following extreme events. Environmental Science & Policy 27, S32S43. https://doi.org/10.1016/j.envsci.2012.09.001.CrossRefGoogle Scholar
Boas, I, Farbotko, C, Adams, H, Sterly, H, Bush, S, van der Geest, K, Wiegel, H, Ashraf, H, Baldwin, A, Bettini, G, Blondin, S, de Bruijn, M, Durand-Delacre, D, Fröhlich, C, Gioli, G, Guaita, L, Hut, E, Jarawura, FX, Lamers, M, Lietaer, S, Nash, SL, Piguet, E, Rothe, D, Sakdapolrak, P, Smith, L, Tripathy Furlong, B, Turhan, E, Warner, J, Zickgraf, C, Black, R and Hulme, M (2019) Climate migration myths. Nature Climate Change 9(12), 901903. https://doi.org/10.1038/s41558-019-0633-3.CrossRefGoogle Scholar
Bongarts Lebbe, T, Rey-Valette, H, Chaumillon, É, Camus, G, Almar, R, Cazenave, A, Claudet, J, Rocle, N, Meur-Férec, C, Viard, F, Mercier, D, Dupuy, C, Ménard, F, Rossel, BA, Mullineaux, L, Sicre, MA, Zivian, A, Gaill, F and Euzen, A (2021) Designing coastal adaptation strategies to tackle sea level rise. Frontiers in Marine Science 8, 740602. https://doi.org/10.3389/fmars.2021.740602.CrossRefGoogle Scholar
Bouwer, LM, Cheong, S-M, Jacot Des Combes, H, Frölicher, TL, McInnes, KL, Ratter, BMW and Rivera-Arriaga, E (2022) Risk management and adaptation for extremes and abrupt changes in climate and oceans: Current knowledge gaps. Frontiers in Climate 3, 785641. https://doi.org/10.3389/fclim.2021.785641.CrossRefGoogle Scholar
Bower, ER, Badamikar, A, Wong-Parodi, G and Field, CB (2023) Enabling pathways for sustainable livelihoods in planned relocation. Nature Climate Change 13(9), 919926. https://doi.org/10.1038/s41558-023-01753-x.CrossRefGoogle Scholar
Brauch, HG and Scheffran, J (2012) Introduction: Climate change, human security, and violent conflict in the anthropocene. In Scheffran, J, Brzoska, M, Brauch, HG, Link, PM and Schilling, J (eds), Climate Change, Human Security and Violent Conflict. Berlin: Springer, pp. 340.CrossRefGoogle Scholar
Brondizio, ES, Vogt, ND, Mansur, AV, Anthony, EJ, Costa, S and Hetrick, S (2016) A conceptual framework for analyzing deltas as coupled social–ecological systems: An example from the Amazon River Delta. Sustainability Science 11(4), 591609. https://doi.org/10.1007/s11625-016-0368-2.CrossRefGoogle Scholar
Brown, K, Naylor, L and Quinn, T (2017) Making space for proactive adaptation of rapidly changing coasts: A windows of opportunity approach. Sustainability 9(8), 1408. https://doi.org/10.3390/su9081408.CrossRefGoogle Scholar
Brown, S, Nicholls, RJ, Bloodworth, A, Bragg, O, Clauss, A, Field, S, Gibbons, L, Pladaitė, M, Szuplewski, M, Watling, J, Shareef, A and Khaleel, Z (2023) Pathways to sustain atolls under rising sea levels through land claim and island raising. Environmental Research: Climate 2(1), 015005. https://doi.org/10.1088/2752-5295/acb4b3.Google Scholar
Buhaug, H and Von Uexkull, N (2021) Vicious circles: Violence, vulnerability, and climate change. Annual Review of Environment and Resources 46(1), 545568. https://doi.org/10.1146/annurev-environ-012220-014708.CrossRefGoogle Scholar
Burn, MJ, Boger, R, Holmes, J and Bain, A (2022) A long-term perspective of climate change in the Caribbean and its impacts on the island of Barbuda. In Perdikaris, S and Boger, R, Barbuda, 1st edn. London: Routledge India, pp. 1139. https://doi.org/10.4324/9781003347996-2.CrossRefGoogle Scholar
Cabana, D, Rölfer, L, Evadzi, P and Celliers, L (2023) Enabling climate change adaptation in coastal systems: A systematic literature review. Earth’s Future 11(8), e2023EF003713. https://doi.org/10.1029/2023EF003713.CrossRefGoogle Scholar
Campanella, R (2010) Delta Urbanism. Chicago, IL: American Planning Association. https://doi.org/10.4324/9781351179737.Google Scholar
Cao, A, Esteban, M, Valenzuela, VPB, Onuki, M, Takagi, H, Thao, ND and Tsuchiya, N (2021) Future of Asian deltaic megacities under sea level rise and land subsidence: Current adaptation pathways for Tokyo, Jakarta, Manila, and Ho Chi Minh City. Current Opinion in Environmental Sustainability 50, 8797. https://doi.org/10.1016/j.cosust.2021.02.010.CrossRefGoogle Scholar
Carlisle, K and Gruby, RL (2019) Polycentric systems of governance: A theoretical model for the commons. Policy Studies Journal 47(4), 927952. https://doi.org/10.1111/psj.12212.CrossRefGoogle Scholar
Carmen, E, Fazey, I, Ross, H, Bedinger, M, Smith, FM, Prager, K, McClymont, K and Morrison, D (2022) Building community resilience in a context of climate change: The role of social capital. Ambio 51(6), 13711387. https://doi.org/10.1007/s13280-021-01678-9.CrossRefGoogle Scholar
Carrillo, J, González, A, Pérez, JC, Expósito, FJ and Díaz, JP (2022) Projected impacts of climate change on tourism in the Canary Islands. Regional Environmental Change 22(2), 61. https://doi.org/10.1007/s10113-022-01880-9.CrossRefGoogle Scholar
Carro, I, Seijo, L, Nagy, GJ, Lagos, X and Gutiérrez, O (2018) Building capacity on ecosystem-based adaptation strategy to cope with extreme events and sea-level rise on the Uruguayan coast. International Journal of Climate Change Strategies and Management 10(4), 504522. https://doi.org/10.1108/IJCCSM-07-2017-0149.CrossRefGoogle Scholar
CHS (2003) Human Security Now, Protecting and Empowering People. New York: Commission on Human Security. Available at https://reliefweb.int/report/world/human-security-now-protecting-and-empowering-people (accessed 26 February 2024)Google Scholar
Cisneros-Montemayor, AM, Pauly, D, Weatherdon, LV and Ota, Y (2016) A global estimate of seafood consumption by coastal indigenous peoples. PLoS One 11(12), e0166681. https://doi.org/10.1371/journal.pone.0166681.CrossRefGoogle ScholarPubMed
Clarke, T, McNamara, KE, Clissold, R and Nunn, PD (2019) Community-based adaptation to climate change: Lessons from Tanna Island, Vanuatu. Island Studies Journal 14(1), 5980. https://doi.org/10.24043/isj.80.CrossRefGoogle Scholar
Cohen-Shacham, E, Walters, G, Janzen, C and Maginnis, S (2016) Nature-Based Solutions to Address Global Societal Challenges. Gland: IUCN.CrossRefGoogle Scholar
Collins, M, Sutherland, M, Bouwer, L, Cheong, S-M, Frolicher, T, Jacot Des Combes, H, Koll Roxy, M, Losada, I, McInnes, L, Ratter, B, Rivera-Arriaga, E, Susanto, D, Swingedouw, D and Tibig, L (2019) Extremes, abrupt changes and managing risk. In Pörtner, H-O, Roberts, DC, Masson-Delmotte, V and Weyer, NM (eds), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge: Cambridge University Press, pp. 589655. https://doi.org/10.1017/9781009157964.008.Google Scholar
Conant, RT, Cerri, CEP, Osborne, BB and Paustian, K (2017) Grassland management impacts on soil carbon stocks: A new synthesis. Ecological Applications 27(2), 662668. https://doi.org/10.1002/eap.1473.CrossRefGoogle Scholar
Connell, J (2016) Last days in the Carteret Islands? Climate change, livelihoods and migration on coral atolls. Asia Pacific Viewpoint 57(1), 315.CrossRefGoogle Scholar
Cooley, S, Schoeman, D, Bopp, L, Boyd, P, Donner, S, Ito, S-I, Kiessling, W, Martinetto, P, Ojea, E, Racault, M-F, Rost, B, Skern-Mauritze, M and Ghebrehiwet, DY (2022) Ocean and coastal ecosystems and their services. In Pörtner, H-O, Roberts, DC, Tignor, MMB and Rama, B (eds), Climate Change 2022: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, pp. 379550. https://doi.org/10.1017/9781009325844.005.Google Scholar
Costanza, R, Anderson, SJ, Sutton, P, Mulder, K, Mulder, O, Kubiszewski, I, Wang, X, Liu, X, Pérez-Maqueo, O, Luisa Martinez, M, Jarvis, D and Dee, G (2021) The global value of coastal wetlands for storm protection. Global Environmental Change 70, 102328. https://doi.org/10.1016/j.gloenvcha.2021.102328.CrossRefGoogle Scholar
Costello, C, Cao, L, Gelcich, S, Cisneros-Mata, , Free, CM, Froehlich, HE, Golden, CD, Ishimura, G, Maier, J, Macadam-Somer, I, Mangin, T, Melnychuk, MC, Miyahara, M, de Moor, CL, Naylor, R, Nøstbakken, L, Ojea, E, O’Reilly, E, Parma, AM, Plantinga, AJ, Thilsted, SH and Lubchenco, J (2020) The future of food from the sea. Nature 588(7836), 95100. https://doi.org/10.1038/s41586-020-2616-y.CrossRefGoogle ScholarPubMed
Cunsolo, A and Ellis, N (2018) Ecological grief as a mental health response to climate change-related loss. Nature Climate Change 8, 275281. https://doi.org/10.1038/s41558-018-0092-2.CrossRefGoogle Scholar
Cutter, SL (2018) Compound, cascading, or complex disasters: What’s in a name? Environment: Science and Policy for Sustainable Development 60(6), 1625. https://doi.org/10.1080/00139157.2018.1517518.Google Scholar
Dahlet, LI, Selim, SA and Van Putten, I (2023) A review of how we study coastal and marine conflicts: Is social science taking a broad enough view? Maritime Studies 22(3), 29. https://doi.org/10.1007/s40152-023-00319-z.CrossRefGoogle Scholar
Dannenberg, AL, Frumkin, H, Hess, JJ and Ebi, KL (2019) Managed retreat as a strategy for climate change adaptation in small communities: Public health implications. Climatic Change 153(1), 114. https://doi.org/10.1007/s10584-019-02382-0.CrossRefGoogle Scholar
Dawson, R, Khan, MSA, Gornitz, V, Lemos, MF, Atkinson, L, Pullen, J, Osorio, JC and Usher, L (2018) Urban areas in coastal zones. In Rosenzweig, C, Solecki, W, Romero-Lankao, P, Mehrotra, S, Dhakal, S and Ibrahim, SA (eds), Climate Change and Cities: Second Assessment Report of the Urban Climate Change Research Network. Cambridge: Cambridge University Press, pp. 319362.CrossRefGoogle Scholar
Donatuto, J, Grossman, EE, Konovsky, J, Grossman, S and Campbell, LW (2014) Indigenous community health and climate change: Integrating biophysical and social science indicators. Coastal Management 42(4), 355373. https://doi.org/10.1080/08920753.2014.923140.CrossRefGoogle Scholar
Donner, SD (2015) The legacy of migration in response to climate stress: Learning from the Gilbertese resettlement in the Solomon Islands. Natural Resources Forum 39(3–4), 191201. https://doi.org/10.1111/1477-8947.12082.CrossRefGoogle Scholar
Dow, K, Berkhout, F and Preston, BL (2013) Limits to adaptation to climate change: A risk approach. Current Opinion in Environmental Sustainability 5(3–4), 384391. https://doi.org/10.1016/j.cosust.2013.07.005.CrossRefGoogle Scholar
Duvat, VKE, Magnan, AK, Goeldner-Gianella, L, Grancher, D, Costa, S, Maquaire, O, le Cozannet, G, Stahl, L, Volto, N and Pignon-Mussaud, C (2022) Internal relocation as a relevant and feasible adaptation strategy in Rangiroa Atoll, French Polynesia. Scientific Reports 12(1), 14183. https://doi.org/10.1038/s41598-022-18109-8.CrossRefGoogle ScholarPubMed
Duvat, VKE, Magnan, AK, Perry, CT, Spencer, T, Bell, JD, Wabnitz, CCC, Webb, AP, White, I, McInnes, KL, Gattuso, JP, Graham, NAJ, Nunn, PD and le Cozannet, G (2021) Risks to future atoll habitability from climate‐driven environmental changes. WIREs Climate Change 12(3), e700. https://doi.org/10.1002/wcc.700.CrossRefGoogle Scholar
Ericson, J, Vorosmarty, C, Dingman, S, Ward, L and Meybeck, M (2006) Effective sea-level rise and deltas: Causes of change and human dimension implications. Global and Planetary Change 50(1–2), 6382. https://doi.org/10.1016/j.gloplacha.2005.07.004.CrossRefGoogle Scholar
Esteban, M, Takagi, H, Jamero, L, Chadwick, C, Avelino, JE, Mikami, T, Fatma, D, Yamamoto, L, Thao, ND, Onuki, M, Woodbury, J, Valenzuela, VPB, Crichton, RN, Shibayama, T (2020) Adaptation to sea level rise: Learning from present examples of land subsidence. Ocean & Coastal Management 189, 104852. https://doi.org/10.1016/j.ocecoaman.2019.104852.CrossRefGoogle Scholar
Farbotko, C (2010) Wishful sinking: Disappearing islands, climate refugees and cosmopolitan experimentation. Asia Pacific Viewpoint 51(1), 4760. https://doi.org/10.1111/j.1467-8373.2010.001413.x.CrossRefGoogle Scholar
Farbotko, C and Campbell, J (2022) Who defines atoll ‘uninhabitability’? Environmental Science & Policy 138, 182190. https://doi.org/10.1016/j.envsci.2022.10.001.CrossRefGoogle Scholar
Farbotko, C, Dun, O, Thornton, F, McNamara, KE and McMichael, C (2020) Relocation planning must address voluntary immobility. Nature Climate Change 10(8), 702704. https://doi.org/10.1038/s41558-020-0829-6.CrossRefGoogle Scholar
Fatorić, S and Chelleri, L (2012) Vulnerability to the effects of climate change and adaptation: The case of the Spanish Ebro Delta. Ocean & Coastal Management 60, 110. https://doi.org/10.1016/j.ocecoaman.2011.12.015.CrossRefGoogle Scholar
Ferris, E and Weerasinghe, S (2020) Promoting human security: Planned relocation as a protection tool in a time of climate change. Journal on Migration and Human Security 8(2), 134149. https://doi.org/10.1177/2331502420909305.CrossRefGoogle Scholar
Flörke, M, Schneider, C and McDonald, RI (2018) Water competition between cities and agriculture driven by climate change and urban growth. Nature Sustainability 1(1), 5158. https://doi.org/10.1038/s41893-017-0006-8.CrossRefGoogle Scholar
Ford, JD, Willox, AC, Chatwood, S, Furgal, C, Harper, S, Mauro, I and Pearce, T (2014) Adapting to the effects of climate change on Inuit health. American Journal of Public Health 104(S3), e9e17. https://doi.org/10.2105/AJPH.2013.301724.CrossRefGoogle Scholar
Forsyth, T (2013) Community-based adaptation: A review of past and future challenges. Wiley Interdisciplinary Reviews: Climate Change 4(5), 439446. https://doi.org/10.1002/wcc.231.Google Scholar
Fox-Kemper, B, Hewitt, HT, Xiao, C, Adalgeirsdottir, G, Drijfhout, SS, Edwards, TL, Golledge, NR, Hemer, M, Kopp, RE, Krinner, G, Mix, A, Notz, D, Nowicki, S, Nurhati, IS, Ruiz, L, Sallee, J-B, Slangen, ABA and Yu, Y (2021) Ocean, cryosphere and sea level change. In Masson-Delmotte, V, Zhai, P, Pirani, A and Zhou, B (eds), Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge and New York: Cambridge University Press, pp. 12111362.Google Scholar
Garrett, JK, Clitherow, TJ, White, MP, Wheeler, BW and Fleming, LE (2019) Coastal proximity and mental health among urban adults in England: The moderating effect of household income. Health & Place 59, 102200. https://doi.org/10.1016/j.healthplace.2019.102200.CrossRefGoogle ScholarPubMed
Gillis, JR (2012) The Human Shore. Chicago, IL: The University of Chicago Press.CrossRefGoogle Scholar
Glaser, M, Christie, P, Diele, K, Dsikowitzky, L, Ferse, S, Nordhaus, I, Schlüter, A, Schwerdtner Mañez, K and Wild, C (2012) Measuring and understanding sustainability-enhancing processes in tropical coastal and marine social-ecological systems. Current Opinion in Environmental Sustainability 4(3), 300308. https://doi.org/10.1016/j.cosust.2012.05.004.CrossRefGoogle Scholar
Glavovic, B, Dawson, R, Chow, W, Garschagen, M, Haasnoot, M, Singh, C and Thomas, A (2022) Cross-chapter paper 2: Cities and settlements by the sea. In Pörtner, HO, Roberts, DC, Tignor, M and Rama, B (eds), Climate Change 2022: Impacts, Adaptation, and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK and New York, NY: Cambridge University Press, pp. 21632194.Google Scholar
Gopalakrishnan, S, Landry, CE, Smith, MD and Whitehead, JC (2016) Economics of coastal erosion and adaptation to sea level rise. Annual Review of Resource Economics 8(1), 119139. https://doi.org/10.1146/annurev-resource-100815-095416.CrossRefGoogle Scholar
Gotham, KF (2016) Coastal restoration as contested terrain: Climate change and the political economy of risk reduction in Louisiana. Sociological Forum 31, 787806. https://doi.org/10.1111/socf.12273.CrossRefGoogle Scholar
Gran Castro, JA and Ramos De Robles, SL (2019) Climate change and flood risk: Vulnerability assessment in an urban poor community in Mexico. Environment and Urbanization 31(1), 7592. https://doi.org/10.1177/0956247819827850.CrossRefGoogle Scholar
Gray, SRJ, Gagnon, AS, Gray, SA, O’Dwyer, B, O’Mahony, C, Muir, D, Devoy, RJN, Falaleeva, M and Gault, J (2014) Are coastal managers detecting the problem? Assessing stakeholder perception of climate vulnerability using fuzzy cognitive mapping. Ocean & Coastal Management 94, 7489. https://doi.org/10.1016/j.ocecoaman.2013.11.008.CrossRefGoogle Scholar
Griggs, G and Reguero, BG (2021) Coastal adaptation to climate change and sea-level rise. Water 13(16), 2151. https://doi.org/10.3390/w13162151.CrossRefGoogle Scholar
Haasnoot, M, Lawrence, J and Magnan, AK (2021) Pathways to coastal retreat. Science 372(6548), 12871290. https://doi.org/10.1126/science.abi6594.CrossRefGoogle ScholarPubMed
Hallegatte, S, Green, C, Nicholls, RJ and Corfee-Morlot, J (2013) Future flood losses in major coastal cities. Nature Climate Change 3(9), 802806. https://doi.org/10.1038/nclimate1979.CrossRefGoogle Scholar
Hanazaki, N, Berkes, F, Seixas, CS and Peroni, N (2013) Livelihood diversity, food security and resilience among the Caiçara of coastal Brazil. Human Ecology 41(1), 153164. https://doi.org/10.1007/s10745-012-9553-9.CrossRefGoogle Scholar
Hari, V, Dharmasthala, S, Koppa, A, Karmakar, S and Kumar, R (2021) Climate hazards are threatening vulnerable migrants in Indian megacities. Nature Climate Change 11(8), 636638. https://doi.org/10.1038/s41558-021-01105-7.CrossRefGoogle Scholar
Harper, S, Adshade, M, Lam, VWY, Pauly, D and Sumaila, UR (2020) Valuing invisible catches: Estimating the global contribution by women to small-scale marine capture fisheries production. PLoS One 15(3), e0228912. https://doi.org/10.1371/journal.pone.0228912.CrossRefGoogle ScholarPubMed
Hauer, ME, Fussell, E, Mueller, V, Burkett, M, Call, M, Abel, K, McLeman, R and Wrathall, D (2020) Sea-level rise and human migration. Nature Reviews Earth & Environment 1(1), 2839. https://doi.org/10.1038/s43017-019-0002-9.CrossRefGoogle Scholar
Hérivaux, C, Rey-Valette, H, Rulleau, B, Agenais, AL, Grisel, M, Kuhfuss, L, Maton, L and Vinchon, C (2018) Benefits of adapting to sea level rise: The importance of ecosystem services in the French Mediterranean sandy coastline. Regional Environmental Change 18(6), 18151828. https://doi.org/10.1007/s10113-018-1313-y.CrossRefGoogle Scholar
Hinkel, J, Aerts, JCJH, Brown, S, Jiménez, JA, Lincke, D, Nicholls, RJ, Scussolini, P, Sanchez-Arcilla, A, Vafeidis, A and Addo, KA (2018) The ability of societies to adapt to twenty-first-century sea-level rise. Nature Climate Change 8(7), 570578. https://doi.org/10.1038/s41558-018-0176-z.CrossRefGoogle Scholar
Hiwasaki, L, Luna, E, Syamsidik and Marçal, JA (2015) Local and indigenous knowledge on climate-related hazards of coastal and small island communities in Southeast Asia. Climatic Change 128(1–2), 3556. https://doi.org/10.1007/s10584-014-1288-8.CrossRefGoogle Scholar
Howland, GJ (2022) A Critical Review of Climate Change on Coastal Infrastructure Systems (MA thesis), Air Force Institute of Technology, Wright-Patterson. Available at https://apps.dtic.mil/sti/citations/AD1173773 (accessed 26 February 2024).Google Scholar
Huddleston, P, Smith, T, White, I and Elrick-Barr, C (2022) Adapting critical infrastructure to climate change: A scoping review. Environmental Science & Policy 135, 6776. https://doi.org/10.1016/j.envsci.2022.04.015.CrossRefGoogle Scholar
Huddleston, P, Smith, TF, White, I and Elrick-Barr, C (2023) What influences the adaptive capacity of coastal critical infrastructure providers? Urban Climate 48, 101416. https://doi.org/10.1016/j.uclim.2023.101416.CrossRefGoogle Scholar
Inácio, M, Karnauskaitė, D, Mikša, K, Gomes, E, Kalinauskas, M and Pereira, P (2020) Nature-based solutions to mitigate coastal floods and associated socioecological impacts. In Ferreira, CSS, Kalantari, Z, Hartmann, T and Pereira, P (eds), Nature-Based Solutions for Flood Mitigation, Vol. 107. Cham: Springer International Publishing, pp. 3558. https://doi.org/10.1007/698_2020_675.CrossRefGoogle Scholar
IPCC (2019) In Pörtner, H-O, Roberts, DC, Masson-Delmotte, V, et al. (eds), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge, UK and New York, NY: Cambridge University Press.Google Scholar
IPCC (2022) Annex II: Glossary. In Pörtner, HO, Roberts, DC, Tignor, M, et al. (eds), Climate Change 2022: Impacts, Adaptation, and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press, pp. 28972930.Google Scholar
Ismail, AM, Singh, S, Sarangi, SK, Srivastava, AK and Bhowmick, MK (2022) Agricultural system transformation for food and income security in coastal zones. In Lama, TD, Burman, D, Mandal, UK, Sarangi, SK and Sen, HS (eds), Transforming Coastal Zone for Sustainable Food and Income Security. Cham: Springer International Publishing, pp. 322. https://doi.org/10.1007/978-3-030-95618-9_1.CrossRefGoogle Scholar
Jordan, A, Huitema, D, Van Asselt, H and Forster, J (eds) (2018) Governing Climate Change: Polycentricity in Action?, 1st edn, Cambridge University Press. https://doi.org/10.1017/9781108284646.CrossRefGoogle Scholar
Jordan, P, Döring, M, Fröhle, P and Ratter, BMW (2023) Exploring past and present dynamics of coastal protection as possible signposts for the future?: A case study on the islands of Amrum and Föhr in the north Frisian Wadden Sea (GER). Journal of Coastal Conservation 27(1), 2. https://doi.org/10.1007/s11852-022-00921-z.CrossRefGoogle Scholar
Kates, RW, Colten, CE, Laska, S and Leatherman, SP (2006) Reconstruction of New Orleans after hurricane Katrina: A research perspective. Proceedings of the National Academy of Sciences 103(40), 1465314660. https://doi.org/10.1073/pnas.0605726103.CrossRefGoogle ScholarPubMed
Kelman, I (2010) Hearing local voices from Small Island Developing States for climate change. Local Environment 15(7), 605619. https://doi.org/10.1080/13549839.2010.498812.Google Scholar
Kelman, I (2015) Difficult decisions: Migration from Small Island Developing States under climate change: MIGRATION, CLIMATE CHANGE AND SIDS. Earth’s Future 3(4), 133142. https://doi.org/10.1002/2014EF000278.CrossRefGoogle Scholar
Kelman, I (2018) Islandness within climate change narratives of Small Island Developing States (SIDS). Island Studies Journal 13(1), 149166. https://doi.org/10.24043/isj.52.CrossRefGoogle Scholar
Kelman, I, Ayeb-Karlsson, S, Rose-Clarke, K, Prost, A, Ronneberg, E, Wheeler, N and Watts, N (2021) A review of mental health and wellbeing under climate change in Small Island Developing States (SIDS). Environmental Research Letters 16(3), 033007. https://doi.org/10.1088/1748-9326/abe57d.CrossRefGoogle ScholarPubMed
Kench, PS, Liang, C, Ford, MR, Owen, SD, Aslam, M, Ryan, EJ, Turner, T, Beetham, E, Dickson, ME, Stephenson, W, Vila-Concejo, A and McLean, RF (2023) Reef islands have continually adjusted to environmental change over the past two millennia. Nature Communications 14(1), 508. https://doi.org/10.1038/s41467-023-36171-2.CrossRefGoogle ScholarPubMed
Khanom, T (2016) Effect of salinity on food security in the context of interior coast of Bangladesh. Ocean & Coastal Management 130, 205212. https://doi.org/10.1016/j.ocecoaman.2016.06.013.CrossRefGoogle Scholar
Kiddle, GL, Bakineti, T, Latai-Niusulu, A, Missack, W, Pedersen Zari, M, Kiddle, R, Chanse, V, Blaschke, P and Loubser, D (2021) Nature-based solutions for urban climate change adaptation and wellbeing: Evidence and opportunities from Kiribati, Samoa, and Vanuatu. Frontiers in Environmental Science 9, 723166. https://doi.org/10.3389/fenvs.2021.723166CrossRefGoogle Scholar
Kind, JM (2014) Economically efficient flood protection standards for the Netherlands: Efficient flood protection standards for the Netherlands. Journal of Flood Risk Management 7(2), 103117. https://doi.org/10.1111/jfr3.12026.CrossRefGoogle Scholar
Kirchner, K (2013) Conflicts and Politics in the Tana Delta, Kenya. An Analysis of the 2012–2013 Clashes and the General and Presidential Elections 2013 (MA thesis), Leiden University, Leiden. Available at https://hdl.handle.net/1887/22835 (accessed 26 February 2024).Google Scholar
Klöck, C, Duvat, VKE and Nunn, PD (2022) Maladaptive diffusion? The spread of hard protection to adapt to coastal erosion and flooding along island coasts in the Pacific and Indian Ocean. Regional Environmental Change 22(4), 136. https://doi.org/10.1007/s10113-022-01989-x.Google Scholar
Kovalevsky, DV and Scheffran, J (2022) A two-period model of coastal urban adaptation supported by climate services. Urban Science 6(4), 65. https://doi.org/10.3390/urbansci6040065.CrossRefGoogle Scholar
Kullenberg, G (2010) Human empowerment: Opportunities from ocean governance. Ocean & Coastal Management 53(8), 405420. https://doi.org/10.1016/j.ocecoaman.2010.06.006.CrossRefGoogle Scholar
Lam, Y, Winch, PJ, Nizame, FA, Broaddus-Shea, ET, Harun, MGD and Surkan, PJ (2022) Salinity and food security in southwest coastal Bangladesh: Impacts on household food production and strategies for adaptation. Food Security 14(1), 229248. https://doi.org/10.1007/s12571-021-01177-5.CrossRefGoogle Scholar
Landry, CE (2011) Coastal erosion as a natural resource management problem: An economic perspective. Coastal Management 39(3), 259281. https://doi.org/10.1080/08920753.2011.566121.CrossRefGoogle Scholar
Lane, K, Charles-Guzman, K, Wheeler, K, Abid, Z, Graber, N and Matte, T (2013) Health effects of coastal storms and flooding in urban areas. A Review and Vulnerability Assessment. Journal of Environmental and Public Health 2013, 113. https://doi.org/10.1155/2013/913064.Google ScholarPubMed
Leifeld, J and Menichetti, L (2018) The underappreciated potential of peatlands in global climate change mitigation strategies. Nature Communications 9(1), 1071. https://doi.org/10.1038/s41467-018-03406-6.CrossRefGoogle ScholarPubMed
Lincke, D and Hinkel, J (2021) Coastal migration due to 21st century sea‐level rise. Earth’s Future 9(5). https://doi.org/10.1029/2020EF001965CrossRefGoogle Scholar
Lincoln Lenderking, H, Robinson, S and Carlson, G (2021) Climate change and food security in Caribbean Small Island Developing States: Challenges and strategies. International Journal of Sustainable Development & World Ecology 28(3), 238245. https://doi.org/10.1080/13504509.2020.1804477.CrossRefGoogle Scholar
Link, PM, Kominek, J and Scheffran, J (2013) Impacts of accelerated sea level rise on the coastal zones of Egypt. Mainzer Geographische Studien 55, 7994.Google Scholar
Mabrouk, M, Jonoski, A, H. P. Oude Essink, G and Uhlenbrook, S (2018) Impacts of sea level rise and groundwater extraction scenarios on fresh groundwater resources in the Nile Delta governorates, Egypt. Water 10(11), 1690. https://doi.org/10.3390/w10111690.CrossRefGoogle Scholar
Mach, KJ, Adger, WN, Buhaug, H, Burke, M, Fearon, JD, Field, CB, Hendrix, CS, Kraan, CM, Maystadt, JF, O’Loughlin, J, Roessler, P, Scheffran, J, Schultz, KA and von Uexkull, N (2020) Directions for research on climate and conflict. Earth’s Future 8(7), e2020EF001532. https://doi.org/10.1029/2020EF001532.CrossRefGoogle ScholarPubMed
MacManus, K, Balk, D, Engin, H, McGranahan, G and Inman, R (2021) Estimating population and urban areas at risk of coastal hazards, 1990–2015: How data choices matter. Earth System Science Data 13(12), 57475801. https://doi.org/10.5194/essd-13-5747-2021.CrossRefGoogle Scholar
Magnan, AK, Bell, R, Duvat, VKE, Ford, JD, Garschagen, M, Haasnoot, M, Lacambra, C, Losada, IJ, Mach, KJ, Noblet, M, Parthasaranthy, D, Sano, M, Vincent, K, Anisimov, A, Hanson, S, Malmström, A, Nicholls, RJ and Winter, G (2023a) Status of global coastal adaptation. Nature Climate Change 13(11), 12131221. https://doi.org/10.1038/s41558-023-01834-x.CrossRefGoogle Scholar
Magnan, AK, Garschagen, M, Gattuso, J-P, Hay, JE, Hilmi, N, Holland, E, Isla, F, Kofinas, G, Losada, IJ, Petzold, J, Ratter, B, Schuur, T, Tabe, T and Van de Wal, R (2019) Cross-chapter box 9: Integrative cross-chapter box on low-Lying Islands and coasts. In Pörtner, H-O, Roberts, DC, Masson-Delmotte, V and Weyer, NM (eds), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge, UK and New York, NY Cambridge University Press, pp. 657674.Google Scholar
Magnan, AK, O’Neill, BC and Garschagen, M (2023b) Further understanding “severe” climate risk. Climate Risk Management 42, 100538. https://doi.org/10.1016/j.crm.2023.100538.CrossRefGoogle Scholar
Magnan, AK, Oppenheimer, M, Garschagen, M, Buchanan, MK, Duvat, VKE, Forbes, DL, Ford, JD, Lambert, E, Petzold, J, Renaud, FG, Sebesvari, Z, van de Wal, RSW, Hinkel, J and Pörtner, H-O (2022) Sea level rise risks and societal adaptation benefits in low-lying coastal areas. Scientific Reports 12(1), 10677. https://doi.org/10.1038/s41598-022-14303-w.CrossRefGoogle ScholarPubMed
Masselink, G, Beetham, E and Kench, P (2020) Coral reef islands can accrete vertically in response to sea level rise. Science Advances 6(24), eaay3656. https://doi.org/10.1126/sciadv.aay3656.CrossRefGoogle ScholarPubMed
Mastrocicco, M and Colombani, N (2021) The issue of groundwater salinization in coastal areas of the Mediterranean region. A review. Water 13(1), 90. https://doi.org/10.3390/w13010090.CrossRefGoogle Scholar
McMichael, C, Dasgupta, S, Ayeb-Karlsson, S and Kelman, I (2020) A review of estimating population exposure to sea-level rise and the relevance for migration. Environmental Research Letters 15(12), 123005. https://doi.org/10.1088/1748-9326/abb398.CrossRefGoogle ScholarPubMed
McMichael, C, Schwerdtle, PN and Ayeb-Karlsson, S (2023) Waiting for the wave, but missing the tide: Case studies of climate-related (im)mobility and health. Journal of Migration and Health 7, 100147. https://doi.org/10.1016/j.jmh.2022.100147.CrossRefGoogle ScholarPubMed
McNamara, KE, Clissold, R, Westoby, R, Piggott-McKellar, AE, Kumar, R, Clarke, T, Namoumou, F, Areki, F, Joseph, E, Warrick, O and Nunn, PD (2020) An assessment of community-based adaptation initiatives in the Pacific Islands. Nature Climate Change 10(7), 628639. https://doi.org/10.1038/s41558-020-0813-1.CrossRefGoogle Scholar
McNamara, KE and Westoby, R (2011) Solastalgia and the gendered nature of climate change: An example from Erub Island, Torres Strait. EcoHealth 8(2), 233236. https://doi.org/10.1007/s10393-011-0698-6.CrossRefGoogle ScholarPubMed
McNamara, KE, Westoby, R, Clissold, R and Chandra, A (2021) Understanding and responding to climate-driven non-economic loss and damage in the Pacific Islands. Climate Risk Management 33, 100336. https://doi.org/10.1016/j.crm.2021.100336.CrossRefGoogle Scholar
Moftakhari, HR, AghaKouchak, A, Sanders, BF, Allaire, M and Matthew, RA (2018) What is nuisance flooding? Defining and monitoring an emerging challenge. Water Resources Research 54(7), 42184227. https://doi.org/10.1029/2018WR022828.CrossRefGoogle Scholar
Mycoo, M, Wairiu, M, Campbell, D, Duvat, V, Golbuu, Y, Maharaj, S, Nalau, J, Nunn, PD, Pinnegar, J and Warrick, O (2022) Small Islands. In Pörtner, HO, Roberts, DC, Tignor, M and Rama, B (eds), Climate Change 2022: Impacts, Adaptation, and Vulnerability. Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK and New York, NY: Cambridge University Press, pp. 20432121.Google Scholar
Neria, Y and Shultz, JM (2012) Mental health effects of hurricane Sandy: Characteristics, potential aftermath, and response. JAMA 308(24), 2571. https://doi.org/10.1001/jama.2012.110700.CrossRefGoogle ScholarPubMed
Niamir, L and Pachauri, S (2023) From social and natural vulnerability to human-centered climate resilient coastal cities. Frontiers in Sustainable Cities 5, 1137641. https://doi.org/10.3389/frsc.2023.1137641.CrossRefGoogle Scholar
Nicholls, RJ, Adger, WN, Hutton, CW and Hanson, SE (eds) (2020) Deltas in the Anthropocene. Cham: Springer International Publishing. https://doi.org/10.1007/978-3-030-23517-8.CrossRefGoogle Scholar
NOAA (2023) Total Economy of Coastal Areas. National Oceanic and Atmospheric Administration (NOAA), Office for Coastal Management, Bureau of Labor Statistics, Bureau of Economic Analysis. Available at https://coast.noaa.gov/digitalcoast/data/coastaleconomy.html (accessed 26 February 2024).Google Scholar
Nunn, PD, Klöck, C and Duvat, V (2021a) Seawalls as maladaptations along island coasts. Ocean & Coastal Management 205, 105554. https://doi.org/10.1016/j.ocecoaman.2021.105554.CrossRefGoogle Scholar
Nunn, PD, Smith, TF and Elrick-Barr, C (2021b) Path dependency and future adaptation of coastal cities: Examples from the Asia-Pacific. Frontiers in Environmental Science 9, 359. https://doi.org/10.3389/fenvs.2021.642385.CrossRefGoogle Scholar
Nurhidayah, L and McIlgorm, A (2019) Coastal adaptation laws and the social justice of policies to address sea level rise: An Indonesian insight. Ocean & Coastal Management 171, 1118. https://doi.org/10.1016/j.ocecoaman.2019.01.011.CrossRefGoogle Scholar
Nyman, E (2013) Oceans of conflict: Determining potential areas of maritime disputes. SAIS Review of International Affairs 33, 514.CrossRefGoogle Scholar
Olsen, E, Kaplan, IC, Ainsworth, C, Fay, G, Gaichas, S, Gamble, R, Girardin, R, Eide, CH, Ihde, TF, Morzaria-Luna, HN, Johnson, KF, Savina-Rolland, M, Townsend, H, Weijerman, M, Fulton, EA and Link, JS (2018) Ocean futures under ocean acidification, marine protection, and changing fishing pressures explored using a worldwide suite of ecosystem models. Frontiers in Marine Science 5, 64. https://doi.org/10.3389/fmars.2018.00064.CrossRefGoogle Scholar
Oppenheimer, M, Glavovic, B, Hinkel, J, Van de Wal, R, Magnan, AK, Abd-Elgawad, A, Cai, R, Cifuentes-Jara, M, Ghosh, T, DeConto, R, Hay, JE, Isla, F, Marzeion, B, Meyssignac, B and Sebesvari, Z (2019) Sea level rise and implications for low-lying Islands, coasts and communities. In Pörtner, H-O, Roberts, DC, Masson-Delmotte, V and Rama, B (eds), IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. Cambridge: Cambridge University Press, pp. 321445.Google Scholar
Ortiz, AM, Chua, P, Salvador, D, Dyngeland, C, Albao, JD and and Abesamis, R (2023a) Impact of tropical cyclones on food security, health and biodiversity. Bulletin of the World Health Organization 101(02), 152154. https://doi.org/10.2471/BLT.22.288838.CrossRefGoogle ScholarPubMed
Ortiz, AMD, Jamero, ML, Crespin, SJ, Smith Ramirez, C, Matias, DMS, Reyes, JJ, Pauchard, A and la Viña, AGM (2023b) The land and sea routes to 2030: A call for greater attention on all small islands in global environmental policy. npj Biodiversity 2(1), 18. https://doi.org/10.1038/s44185-023-00023-5.CrossRefGoogle Scholar
Ovink, H (2015) Urban Deltas: Water-Related Climate Impacts. Report of Working Group 6. Planetary Security Conference, The Hague, the Netherlands, 2–3 Nov. 2015.Google Scholar
Padawangi, R (2012) Climate change and the north coast of Jakarta: Environmental justice and the social construction of space in urban poor communities. In Holt, WG (ed.), Research in Urban Sociology, Vol. 12. Leeds, UK: Emerald Group Publishing Limited, pp. 321339. https://doi.org/10.1108/S1047-0042(2012)0000012016.Google Scholar
Pal, I, Kumar, A and Mukhopadhyay, A (2023) Risks to coastal critical infrastructure from climate change. Annual Review of Environment and Resources, 48(1), 681712. https://doi.org/10.1146/annurev-environ-112320-101903.CrossRefGoogle Scholar
Paldor, A and Michael, HA (2021) Storm surges cause simultaneous salinization and freshening of coastal aquifers, exacerbated by climate change. Water Resources Research 57(5), e2020WR029213. https://doi.org/10.1029/2020WR029213.CrossRefGoogle Scholar
Pelling, M and Blackburn, S (2013) Megacities and the Coast: Risk, Resilience and Transformation. Abingdon, Oxon: Routledge.Google Scholar
Pereira Santos, A, Rodriguez-Lopez, JM, Chiarel, C and Scheffran, J (2022) Unequal landscapes: Vulnerability traps in informal settlements of the Jacuí River Delta (Brazil). Urban Science 6(4), 76. https://doi.org/10.3390/urbansci6040076.CrossRefGoogle Scholar
Petzold, J, Joe, ET, Kelman, I, Magnan, AK, Mirbach, C, Nagle Alverio, G, Nunn, PD, Ratter, BMW and The Global Adaptation Mapping Initiative Team (2023) Between tinkering and transformation: A contemporary appraisal of climate change adaptation research on the world’s islands. Frontiers in Climate 4, 1072231. https://doi.org/10.3389/fclim.2022.1072231.CrossRefGoogle Scholar
Petzold, J and Magnan, AK (2019) Climate change: Thinking small islands beyond Small Island Developing States (SIDS). Climatic Change 152(1), 145165. https://doi.org/10.1007/s10584-018-2363-3.CrossRefGoogle Scholar
Petzold, J and Ratter, BMW (2015) Climate change adaptation under a social capital approach – An analytical framework for small islands. Ocean & Coastal Management 112, 3643. https://doi.org/10.1016/j.ocecoaman.2015.05.003.CrossRefGoogle Scholar
Philippenko, X and Le Cozannet, G (2023) Social science to accelerate coastal adaptation to sea-level rise. Cambridge Prisms: Coastal Futures 1, 143. https://doi.org/10.1017/cft.2023.25.Google Scholar
Phillips, C and Murphy, C (2021) Solastalgia, place attachment and disruption: Insights from a coastal community on the front line. Regional Environmental Change 21(2), 46. https://doi.org/10.1007/s10113-021-01778-y.CrossRefGoogle Scholar
Piggott-McKellar, AE and McMichael, C (2021) The immobility-relocation continuum: Diverse responses to coastal change in a small island state. Environmental Science & Policy 125, 105115. https://doi.org/10.1016/j.envsci.2021.08.019.CrossRefGoogle Scholar
Piggott-McKellar, AE, McNamara, KE, Nunn, PD and Watson, JEM (2019) What are the barriers to successful community-based climate change adaptation? A review of grey literature. Local Environment 24(4), 374390. https://doi.org/10.1080/13549839.2019.1580688.CrossRefGoogle Scholar
Posen, PE, Beraud, C, Harper Jones, C, Tyllianakis, E, Joseph-Witzig, A and St. Louis, A (2023) Vulnerability of coastal infrastructure and communities to extreme storms and rising sea levels: An improved model for Grenada and its dependencies. Land 12(7), 1418. https://doi.org/10.3390/land12071418.CrossRefGoogle Scholar
Powell, N, Kløcker Larsen, R, De Bruin, A, Powell, S and Elrick-Barr, C (2017) Water security in times of climate change and intractability: Reconciling conflict by transforming security concerns into equity concerns. Water 9(12), 934. https://doi.org/10.3390/w9120934.CrossRefGoogle Scholar
Pugatch, T (2019) Tropical storms and mortality under climate change. World Development 117, 172182. https://doi.org/10.1016/j.worlddev.2019.01.009.CrossRefGoogle Scholar
Rahman, MS, Zulfiqar, F, Ullah, H, Himanshu, SK and Datta, A (2023) Status and drivers of households’ food security status in climate-sensitive coastal areas of Bangladesh: A comparison between the exposed and interior coasts. International Journal of Sustainable Development & World Ecology 30(1), 8194. https://doi.org/10.1080/13504509.2022.2123409.CrossRefGoogle Scholar
Rakib, MA, Sasaki, J, Matsuda, H, Quraishi, SB, Mahmud, MJ, Bodrud-Doza, M, Ullah, AKMA, Fatema, KJ, Newaz, MA and Bhuiyan, MAH (2020) Groundwater salinization and associated co-contamination risk increase severe drinking water vulnerabilities in the southwestern coast of Bangladesh. Chemosphere 246, 125646. https://doi.org/10.1016/j.chemosphere.2019.125646.CrossRefGoogle ScholarPubMed
Ratter, B and Leyshon, C (2021) Perceptions of and resilience to coastal climate risks. In: von Storch, H (ed.), Oxford Research Encyclopedia of Climate Science. Oxford: Oxford University Press. https://doi.org/10.1093/acrefore/9780190228620.013.819.Google Scholar
Rawlani, AK and Sovacool, BK (2011) Building responsiveness to climate change through community based adaptation in Bangladesh. Mitigation and Adaptation Strategies for Global Change 16(8), 845863. https://doi.org/10.1007/s11027-011-9298-6.CrossRefGoogle Scholar
Reimann, L, Jones, B, Bieker, N, Wolff, C, Aerts, JCJH and Vafeidis, AT (2023a) Exploring spatial feedbacks between adaptation policies and internal migration patterns due to sea-level rise. Nature Communications 14(1), 2630. https://doi.org/10.1038/s41467-023-38278-y.CrossRefGoogle ScholarPubMed
Reimann, L, Vafeidis, AT and Honsel, LE (2023b) Population development as a driver of coastal risk: Current trends and future pathways. Cambridge Prisms: Coastal Futures 1, e14. https://doi.org/10.1017/cft.2023.3.Google Scholar
Roberts, DA, Johnston, EL and Knott, NA (2010) Impacts of desalination plant discharges on the marine environment: A critical review of published studies. Water Research 44(18), 51175128. https://doi.org/10.1016/j.watres.2010.04.036.CrossRefGoogle ScholarPubMed
Rölfer, L, Celliers, L and Abson, DJ (2022) Resilience and coastal governance: Knowledge and navigation between stability and transformation. Ecology and Society 27(2), art40. https://doi.org/10.5751/ES-13244-270240.CrossRefGoogle Scholar
Rölfer, L, Winter, G, Máñez Costa, M and Celliers, L (2020) Earth observation and coastal climate services for small islands. Climate Services 18, 100168. https://doi.org/10.1016/j.cliser.2020.100168.CrossRefGoogle Scholar
Romero-Lankao, P, Gnatz, DM and Sperling, JB (2016) Examining urban inequality and vulnerability to enhance resilience: Insights from Mumbai, India. Climatic Change 139(3–4), 351365. https://doi.org/10.1007/s10584-016-1813-z.CrossRefGoogle Scholar
Scheffran, J (2022) Climate change: Human security between conflict and cooperation. In Kurtz, LR (ed.), Encyclopedia of Violence, Peace, & Conflict. London, UK, San Diego, CA: Elsevier and Cambridge, MA: Oxford, pp. 807819. https://doi.org/10.1016/B978-0-12-820195-4.00087-X.CrossRefGoogle Scholar
Scheffran, J and Link, PM (2019) Städtische Agglomerationen in Flussdeltagebieten. In Lozan, J, Breckle, LS-W, Grassl, H, Kuttler, W and Matzarakis, A (eds), Warnsignal Klima: Die Städte. Hamburg: Verlag Wissenschaftliche Auswertungen in Kooperation Mit GEO Magazin-Hamburg, pp. 9198.Google Scholar
Scheres, B and Schüttrumpf, H (2020) Nature-based solutions in coastal research – A new challenge for coastal engineers? In Viet, NT, Xiping, D and Tung, TT (eds), APAC 2019. Singapore: Springer Singapore, pp. 13831389. https://doi.org/10.1007/978-981-15-0291-0_187.CrossRefGoogle Scholar
Schueler, K (2017) Nature-Based Solutions to Enhance Coastal Resilience. Washington, DC: Inter-American Development Bank.CrossRefGoogle Scholar
Seddon, N, Turner, B, Berry, P, Chausson, A and Girardin, CAJ (2019) Grounding nature-based climate solutions in sound biodiversity science. Nature Climate Change 9(2), 8487. https://doi.org/10.1038/s41558-019-0405-0.CrossRefGoogle Scholar
Seneviratne, SI, Zhang, X, Adnan, M, Badi, W, Dereczynski, C, Di Luca, A, Ghosh, S, Iskandar, I, Kossin, J, Lewis, S, Otto, F, Pinto, I, Satoh, M, Vicente-Serrano, SM, Wehner, M and Zhou, B (2021) Weather and climate extreme events in a changing climate. In Masson-Delmotte, V, Zhai, P, Pirani, A and Zhou, B (eds), Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge and New York: Cambridge University Press, pp. 15131766.Google Scholar
Sengupta, S, Kovalevsky, DV, Bouwer, LM and Scheffran, J (2023) Urban planning of coastal adaptation under sea-level rise: An agent-based model in the VIABLE framework. Urban Science 7(3), 79. https://doi.org/10.3390/urbansci7030079.CrossRefGoogle Scholar
Senhoury, A, Niang, A, Diouf, B and Thomas, Y-F (2016) Managing flood risks using nature-based solutions in Nouakchott, Mauritania. In Renaud, FG, Sudmeier-Rieux, K, Estrella, M and Nehren, U (eds), Ecosystem-Based Disaster Risk Reduction and Adaptation in Practice, Vol. 42. Cham: Springer International Publishing, pp. 435455. https://doi.org/10.1007/978-3-319-43633-3_19.CrossRefGoogle Scholar
Shams, S and Shohel, MMC (2016) Food security and livelihood in coastal area under increased salinity and frequent tidal surge. Environment and Urbanization ASIA 7(1), 2237. https://doi.org/10.1177/0975425315619046.CrossRefGoogle Scholar
Siders, AR (2019) Social justice implications of US managed retreat buyout programs. Climatic Change 152(2), 239257. https://doi.org/10.1007/s10584-018-2272-5.CrossRefGoogle Scholar
Sithara, S, Pramada, SK and Thampi, SG (2020) Impact of projected climate change on seawater intrusion on a regional coastal aquifer. Journal of Earth System Science 129(1), 218. https://doi.org/10.1007/s12040-020-01485-y.CrossRefGoogle Scholar
Smith, KA, Dowling, CE and Brown, J (2019) Simmered then boiled: Multi-decadal poleward shift in distribution by a temperate fish accelerates during marine heatwave. Frontiers in Marine Science 6, 407. https://doi.org/10.3389/fmars.2019.00407.CrossRefGoogle Scholar
Sorensen, RM (2006) Basic Coastal Engineering. New York: Springer. https://doi.org/10.1007/b101261.Google Scholar
Spalding, AK and Biedenweg, K (2017) Socializing the coast: Engaging the social science of tropical coastal research. Estuarine, Coastal and Shelf Science 187, 18. https://doi.org/10.1016/j.ecss.2017.01.002.CrossRefGoogle Scholar
Spencer, T, Magnan, AK, Donner, S, Garschagen, M, Ford, J, Duvat, VKE and Wabnitz, CCC (2024) Habitability of low-lying socio-ecological systems under a changing climate. Climatic Change 177(1), 14. https://doi.org/10.1007/s10584-023-03675-1.CrossRefGoogle Scholar
Spijkers, J, Merrie, A, Wabnitz, CCC, Osborne, M, Mobjörk, M, Bodin, Ö, Selig, ER, le Billon, P, Hendrix, CS, Singh, GG, Keys, PW and Morrison, TH (2021) Exploring the future of fishery conflict through narrative scenarios. One Earth 4(3), 386396. https://doi.org/10.1016/j.oneear.2021.02.004.CrossRefGoogle Scholar
Steiner, NS, Cheung, WWL, Cisneros-Montemayor, AM, Drost, H, Hayashida, H, Hoover, C, Lam, J, Sou, T, Sumaila, UR, Suprenand, P, Tai, TC and VanderZwaag, DL (2019) Impacts of the changing ocean-sea ice system on the key forage fish Arctic cod (Boreogadus Saida) and subsistence fisheries in the Western Canadian Arctic—Evaluating linked climate, ecosystem and economic (CEE) models. Frontiers in Marine Science 6, 179. https://doi.org/10.3389/fmars.2019.00179.CrossRefGoogle Scholar
Stepanova, O and Bruckmeier, K (2013) The relevance of environmental conflict research for coastal management. A review of concepts, approaches and methods with a focus on Europe. Ocean & Coastal Management 75, 2032. https://doi.org/10.1016/j.ocecoaman.2013.01.007.CrossRefGoogle Scholar
Sterling, EJ, Pascua, P, Sigouin, A, Gazit, N, Mandle, L, Betley, E, Aini, J, Albert, S, Caillon, S, Caselle, JE, Cheng, SH, Claudet, J, Dacks, R, Darling, ES, Filardi, C, Jupiter, SD, Mawyer, A, Mejia, M, Morishige, , Nainoca, W, Parks, J, Tanguay, J, Ticktin, T, Vave, R, Wase, V, Wongbusarakum, S and McCarter, J (2020) Creating a space for place and multidimensional well-being: Lessons learned from localizing the SDGs. Sustainability Science 15(4), 11291147. https://doi.org/10.1007/s11625-020-00822-w.CrossRefGoogle Scholar
Storbjörk, S and Hedrén, J (2011) Institutional capacity-building for targeting sea-level rise in the climate adaptation of Swedish coastal zone management. Lessons from Coastby. Ocean & Coastal Management 54(3), 265273. https://doi.org/10.1016/j.ocecoaman.2010.12.007.CrossRefGoogle Scholar
Syvitski, JPM, Kettner, AJ, Overeem, I, Hutton, EWH, Hannon, MT, Brakenridge, GR, Day, J, 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/ngeo629.CrossRefGoogle Scholar
Taillardat, P, Thompson, BS, Garneau, M, Trottier, K and Friess, DA (2020) Climate change mitigation potential of wetlands and the cost-effectiveness of their restoration. Interface Focus 10(5), 20190129. https://doi.org/10.1098/rsfs.2019.0129.CrossRefGoogle ScholarPubMed
Tessler, ZD, Vörösmarty, CJ, Grossberg, M, Gladkova, I, Aizenman, H, Syvitski, JPM 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.aab3574.CrossRefGoogle ScholarPubMed
Thomas, A, Baptiste, A, Martyr-Koller, R, Pringle, P and Rhiney, K (2020) Climate Change and Small Island Developing States. Annual Review of Environment and Resources 45, 120. https://doi.org/10.1146/annurev-environ-012320-083355.CrossRefGoogle Scholar
Thomas, A and Benjamin, L (2020) Non-economic loss and damage: Lessons from displacement in the Caribbean. Climate Policy 20(6), 715728. https://doi.org/10.1080/14693062.2019.1640105.CrossRefGoogle Scholar
Thomas, A, Theokritoff, E, Lesnikowski, A, Reckien, D, Jagannathan, K, Cremades, R, Campbell, D, Joe, ET, Sitati, A, Singh, C, Segnon, AC, Pentz, B, Musah-Surugu, JI, Mullin, CA, Mach, KJ, Gichuki, L, Galappaththi, E, Chalastani, VI, Ajibade, I, Ruiz-Diaz, R, Grady, C, Garschagen, M, Ford, J, Bowen, K and Global Adaptation Mapping Initiative Team (2021) Global evidence of constraints and limits to human adaptation. Regional Environmental Change 21(3), 85. https://doi.org/10.1007/s10113-021-01808-9.CrossRefGoogle Scholar
Tompkins, EL, Few, R and Brown, K (2008) Scenario-based stakeholder engagement: Incorporating stakeholders preferences into coastal planning for climate change. Journal of Environmental Management 88(4), 15801592. https://doi.org/10.1016/j.jenvman.2007.07.025.CrossRefGoogle ScholarPubMed
Tran, TQ and Van Vu, H (2021) The impact of land fragmentation on food security in the north central coast, Vietnam. Asia & the Pacific Policy Studies 8(2), 327345. https://doi.org/10.1002/app5.330.CrossRefGoogle Scholar
Vianna, GMS, Zeller, D and Pauly, D (2020) Fisheries and policy implications for human nutrition. Current Environmental Health Reports 7(3), 161169. https://doi.org/10.1007/s40572-020-00286-1.CrossRefGoogle ScholarPubMed
Wang, J and Hong, B (2021) Threat posed by future sea-level rise to freshwater resources in the upper Pearl River estuary. Journal of Marine Science and Engineering 9(3), 291. https://doi.org/10.3390/jmse9030291.CrossRefGoogle Scholar
Weatherdon, LV, Magnan, AK, Rogers, AD, Sumaila, UR and Cheung, WWL (2016) Observed and projected impacts of climate change on marine fisheries, aquaculture, coastal tourism, and human health: An update. Frontiers in Marine Science 3, 48. https://doi.org/10.3389/fmars.2016.00048.CrossRefGoogle Scholar
Weir, T and Virani, Z (2011) Three linked risks for development in the Pacific Islands: Climate change, disasters and conflict. Climate and Development 3(3), 193208. https://doi.org/10.1080/17565529.2011.603193.CrossRefGoogle Scholar
Westoby, R, McNamara, KE, Kumar, R and Nunn, PD (2020) From community-based to locally led adaptation: Evidence from Vanuatu. Ambio 49(9), 14661473. https://doi.org/10.1007/s13280-019-01294-8.CrossRefGoogle ScholarPubMed
Wolf, F, Filho, WL, Singh, P, Scherle, N, Reiser, D, Telesford, J, Miljković, IB, Havea, PH, Li, C, Surroop, D and Kovaleva, M (2021) Influences of climate change on tourism development in small Pacific Island states. Sustainability 13(8), 4223. https://doi.org/10.3390/su13084223.CrossRefGoogle Scholar
Yang, L, Scheffran, J, Qin, H and You, Q (2015) Climate-related flood risks and urban responses in the Pearl River Delta, China. Regional Environmental Change 15(2), 379391. https://doi.org/10.1007/s10113-014-0651-7.CrossRefGoogle Scholar
Yang, LE, Chan, FKS and Scheffran, J (2018) Climate change, water management and stakeholder analysis in the Dongjiang River basin in South China. International Journal of Water Resources Development 34(2), 166191. https://doi.org/10.1080/07900627.2016.1264294.CrossRefGoogle Scholar
Zimmermann, S, Dermody, BJ, Theunissen, B, Wassen, MJ, Divine, LM, Padula, VM, von Wehrden, H and Dorresteijn, I (2023) A leverage points perspective on Arctic indigenous food systems research: A systematic review. Sustainability Science 18(3), 14811500. https://doi.org/10.1007/s11625-022-01280-2.CrossRefGoogle Scholar
Zou, Z, Zhang, Y-Y, Lee, S-H and Tsai, S-C (2023) The transformation of coastal governance, from human ecology to local state, in the Jimei peninsula, Xiamen, China. Water 15(14), 2659. https://doi.org/10.3390/w15142659.CrossRefGoogle Scholar
Figure 0

Figure 1. Framework for coastal human security assessments, building on translated general human security dimensions (Adger et al., 2014) into specific dimensions of human security for coastal hotspots in this review.

Author comment: Climate change and human security in coastal regions — R0/PR1

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.pr1 [Opens in a new window]
Jan Petzold [Opens in a new window] Ludwig-Maximilians-Universität München, Germany
Revision round: 0
Role: author

Comments

No accompanying comment.

Recommendation: Climate change and human security in coastal regions — R0/PR2

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.pr2 [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:  02 January 2024
Revision round: 0
Role: Handling Editor
Recommendation/decision: minor-revision

Comments

This is a well written paper that makes many good points. It is highly appropriate to the journal. It does however need some further work, particularly to the Introduction and Conclusions, as recognised by Reviewer 1. This is a crowded field and some re-writing here would indicate the distinctive contribution of this particular paper. There is something of a tendency to make blanket statements but then to negate those statements by stressing regional and local variability. As Reviewer 1 notes, there is some confusion of implementation strategies with governance and the paper could helpfully do with more consideration of governance issues directly. There are some additional points in the annotated version of the ms attached. Overall, however, it is my view that the changes asked for fall under the heading ‘minor revision’

Decision: Climate change and human security in coastal regions — R0/PR3

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.pr3 [Opens in a new window]
Tom Spencer [Opens in a new window] Geography, Cambridge University, United Kingdom of Great Britain and Northern Ireland
Revision round: 0
Role: Editor in Chief
Recommendation/decision: minor-revision

Comments

No accompanying comment.

Author comment: Climate change and human security in coastal regions — R1/PR4

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.pr4 [Opens in a new window]
Jan Petzold [Opens in a new window] Ludwig-Maximilians-Universität München, Germany
Revision round: 1
Role: author

Comments

Dear Editor,

Thank you very much for your constructive feedback and synthesis of the review comments.

We tried to address all the comments as specified in the response to the decision letter. Therefore, we are now around 6000 words, but believe that our article provides a comprehensive review of human security literature in the context of climate change.

Please let us know if there are any further revisions required.

We look forward to your feedback.

Best regards,

Jan Petzold and Jürgen Scheffran

Recommendation: Climate change and human security in coastal regions — R1/PR5

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.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:  02 February 2024
Revision round: 1
Role: Handling Editor
Recommendation/decision: accept

Comments

Very thorough and thoughtful response to the comments made by Reviewer 1 and the Handling Editor. Accept.

Decision: Climate change and human security in coastal regions — R1/PR6

Published online by Cambridge University Press:  12 February 2024
DOI: https://doi.org/10.1017/cft.2024.2.pr6 [Opens in a new window]
Tom Spencer [Opens in a new window] Geography, Cambridge University, United Kingdom of Great Britain and Northern Ireland
Revision round: 1
Role: Editor in Chief
Recommendation/decision: accept

Comments

No accompanying comment.