Climatic Change, the Built Environment, and Urban Resilience: Global Insights and Nigerian Perspectives

Raufu Khairat Adedoyin; Ojuolape Ayonitemi Olawale; Ayejuyo Oreofe Olaotan; Ayoola Razzaq Abayomi

doi:10.18535/ijsrm/v13i11.fe01

Abstract

Climate change presents an escalating global threat to ecosystems, economies, and human settlements. The built environment encompassing buildings, neighborhoods, and infrastructure both contributes significantly to greenhouse gas emissions and remains among the most vulnerable sectors to climate-related disruptions. In Nigeria, rural areas experience increasing drought, desertification, and food insecurity, while urban centers face challenges such as rising temperatures, water scarcity, flooding, and sea-level rise.

This paper adopts a literature-based analytical approach to explore how architecture can serve as a critical tool for climate adaptation and urban resilience. International and local case studies were examined, including Rotterdam’s floating architecture in the Netherlands, which demonstrates how innovative design responds to rising water levels, and the Makoko Floating School in Lagos, which exemplifies community-driven adaptation in a low-resource context. Findings indicate that climate change alters the built environment through intensified heatwaves, flooding, and structural degradation, with unregulated urbanization amplifying exposure. Adaptation strategies such as resilient design, green infrastructure, modular construction, and water-sensitive urban planning are essential to safeguard cities. Complementary mitigation strategies emphasizing low-carbon materials, passive design, and urban vegetation further reduce environmental impact. Both high-technology approaches in developed contexts and low-cost innovations in developing regions provide replicable pathways toward resilience.

In conclusion, architecture plays a pivotal role in addressing climate change through sustainable design and planning. While Nigeria’s progress in climate-responsive architecture remains limited by high construction costs and weak regulatory enforcement, these barriers can be overcome by strengthening building codes, investing in resilient infrastructure, promoting sustainable materials, improving climate data collection, and enhancing institutional and community capacity for adaptation.

Keywords

Climate ChangeArchitectural AdaptationBuilt EnvironmentUrban ResilienceSustainable

References

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[refR-2] Adegun, O. B. (2017). Informal settlements and urban resilience: The case of Makoko, Lagos. Journal of Urbanism, 10(2), 188–209.Google Scholar ↗

[refR-3] Adelekan, I. O. (2010). Vulnerability of poor urban coastal communities to climate change in Lagos, Nigeria. Environment and Urbanization, 22(2), 433–450.Google Scholar ↗

[refR-4] https://doi.org/10.1177/0956247810380141DOI ↗Google Scholar ↗

[refR-5] Adeyemi, K. (2017). MFS II: A new prototype for floating communities. NLÉ Architects.Google Scholar ↗

[refR-6] Agboola, O. P., Ajibade, I., & Adebayo, A. A. (2023). Climate risks and adaptation in Lagos’ informal settlements. Cities, 139, 104324.Google Scholar ↗

[refR-7] Ajibade, I. (2017). Can a future city enhance urban resilience and sustainability? A political ecology analysis of Eko Atlantic City, Nigeria. International Journal of Urban and Regional Research, 41(6), 845–861.Google Scholar ↗

[refR-8] Boano, C., & Hunter, W. (2012). Architecture at risk: The case of Makoko floating school. Open House International, 37(4), 22–31.Google Scholar ↗

[refR-9] Bos, M., & Zwaneveld, P. (2017). Adaptive water management in the Netherlands. Journal of Flood Risk Management, 10(2), 154–162.Google Scholar ↗

[refR-10] Briera, P., & Lefèvre, J. (2024). Policy implementation gaps in climate governance: Challenges for sustainable urban transitions. Journal of Environmental Policy, 36(2), 112–128.Google Scholar ↗

[refR-11] Change, O. C. (2007). Intergovernmental panel on climate change. World Meteorological Organization, 52(1-43), 1.Google Scholar ↗

[refR-12] Demisse Negesse, M., Hishe, S., & Getahun, K. (2024). LULC dynamics and the effects of urban green spaces in cooling and mitigating micro-climate change and urban heat island effects: a case study in Addis Ababa City, Ethiopia. Journal of Water and Climate Change, 15(7), 3033-3055.Google Scholar ↗

[refR-13] Eisenack, K., Moser, S. C., Hoffmann, E., Klein, R. J. T., Oberlack, C., Pechan, A., Rotter, M., & Termeer, C. J. A. M. (2014). Explaining and overcoming barriers to climate change adaptation. Nature Climate Change, 4(10), 867–872.Google Scholar ↗

[refR-14] Gerritsen, H. (2005). What happened in 1953? The Big Flood in the Netherlands in retrospect. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 363(1831), 1271–1291.Google Scholar ↗

[refR-15] IPCC. (2021). Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press. https://www.ipcc.ch/report/ar6/wg1/Google Scholar ↗

[refR-16] Iping, A., Gebreselassie, Y., & van der Hoeven, F. (2019). The urban heat island effect and climate adaptation in African cities. Urban Climate, 29, 100490.Google Scholar ↗

[refR-17] Jha, M. K., & Dev, M. (2024). Impacts of climate change. In Smart internet of things for environment and healthcare (pp. 139-159). Cham: Springer Nature Switzerland. Koen Olthuis, & Keuning, D. (2010). Float!: Building on water to combat urban congestion and climate change. Frame Publishers.Google Scholar ↗

[refR-18] Lobo, M., Chen, Y., & Mensah, K. (2023). Institutional fragmentation and the limits of climate adaptation in urban governance. Cities, 140, 103452.Google Scholar ↗

[refR-19] Neumann, B. (2011). Floating architecture as an adaptation strategy to sea-level rise: The case of the Netherlands. Climate Policy, 11(5), 1–14.Google Scholar ↗

[refR-20] Obada, D. O., Muhammad, M., Tajiri, S. B., Kekung, M. O., Abolade, S. A., Akinpelu, S. B., & Akande, A. (2024). A review of renewable energy resources in Nigeria for climate change mitigation. Case Studies in Chemical and Environmental Engineering, 9, 100669.Google Scholar ↗

[refR-21] OECD. (2014). Water governance in the Netherlands: Fit for the future? OECD Publishing.Google Scholar ↗

[refR-22] Satterthwaite, D., Archer, D., Colenbrander, S., Dodman, D., Hardoy, J., & Patel, S. (2020). Building resilience to climate change in informal settlements. One Earth, 2(2), 143– 156.Google Scholar ↗

[refR-23] Shah, R., Patel, D., & Kim, S. (2024). Technology gaps in sustainable construction: Barriers to global diffusion. Sustainable Built Environment Review, 12(1), 45–63.Google Scholar ↗

[refR-24] Slovic, A., Rodrigues, C., & Silva, R. (2024). Barriers to climate adaptation in the built environment: Lessons from global south cities. Environmental Sustainability Journal,15(3), 201–219.Google Scholar ↗

[refR-25] UN-Habitat. (2020). World Cities Report 2020: The Value of Sustainable Urbanization. Nairobi: UN-Habitat. https://unhabitat.org/wcr/Google Scholar ↗

[refR-26] Van Koningsveld, M., Mulder, J. P. M., Stive, M. J. F., van der Valk, L., & van der Weck, A. W. (2008). Living with sea-level rise and climate change: A case study of the Netherlands. Journal of Coastal Research, 24(2), 367–379.Google Scholar ↗

[refR-27] Wang, J., Chen, X., & Li, H. (2025). Coastal cities and sea-level rise: Global lessons for resilience. Ocean and Coastal Management, 240, 106594.Google Scholar ↗