Green and Sustainable Synthesis of Iron Oxide-Based Nanomaterials for Energy and Environmental Applications, 2026, Pages 283-310
The phenomenon of rapid industrialization and the subsequent rise in energy consumption have led to the exploitation of natural resources, specifically fossil fuels, for the purpose of power generation. The observed phenomenon leads to introduction a substantial quantity of carbon dioxide (CO2) as a greenhouse gas into the surrounding environment. The effects of CO2 emissions are one of today’s most pressing problems for society. In this context, there has been a lot of interest in the most recent advancement made in a comprehensive CO2 capture strategy. There are many different methods for separating and capturing CO2, including liquid absorption, adsorption on solid surfaces, chemical looping, gas phase separation, and hybrid processes like adsorption-membrane systems. Due to CO2 relatively stable dynamic state, interacting with other substances is complex. Therefore, it is necessary to create specific catalysts that can dissolve the CO2 bond and be used as a feedstock to create highly economical materials. Recently, there has been a lot of interest in using metal oxide-based processes to convert CO2 into other compounds. Metal oxides are essential to CO2 hydrogenation because they offer extra benefits like selectivity and energy efficiency. This book chapter focuses on iron oxide based materials and their utilization in the context of CO2 capture applications. Here, a curated literature review on iron oxide-based materials for CO2 capture application has been presented, and the various strategies used by scientists and industry to reestablish the equilibrium of CO2 in the environment have been analyzed.
Green and Sustainable Synthesis of Iron Oxide-Based Nanomaterials for Energy and Environmental Applications, 2026, Pages 79-109
The scientific community worldwide has been interested in nanoscience over the past few decades due to its potential applications in the energy, pharmaceutical, agricultural, electronics, medical diagnostics, and chemical industries, as well as in space exploration. These distinctive features of iron oxide nanoparticles (IONPs) can be explored for various additional applications, including medication delivery, biosensing, reusable catalysts, antibacterial and anticancer properties, MRI agents, and medical imaging. Therefore, it is essential to fabricate IONPs with the appropriate monodispersity, structure, size, and topology for the applications. The biofabrication of IONPs with the appropriate nature and structure utilizing microbial machinery is safer, faster, and more ecologically friendly than previous approaches. Many microorganisms have previously been investigated for their ability to fabricate IONPs. As a result, manufacturing IONPs using microorganisms is a novel approach that shows great promise. This chapter offers detailed information on several methods for producing IONPs utilizing microbial cells, as well as their multifunctional applications.
Habeebulahi Ajibola Adekilekun, Olorunshola Dave Omodamiro, Ngozi Kalu Achi, Habeebat Adekilekun Oyewusi, Racheal M. Omodamiro, Bashar Adekilekun Tijani, Oluwatosin Olubunmi Oladipo, Fahrul Hayup,
Chapter 5 - Impact of marine pollution on marine microbial products,
Editor(s): Sesan Abiodun Aransiola, Mariam Iyabo Adeoba, Naga Raju Maddela,
Marine Microbial Products,
Academic Press,
2026,
Pages 121-135,
ISBN 9780443438363,
https://doi.org/10.1016/B978-0-443-43836-3.00012-4.
This chapter explores how pollutants such as microplastics and oil spills disrupt marine microbial communities and ocean ecosystem health, highlighting the need to reduce marine pollution and protect biodiversity in line with SDG 14 (Life Below Water). By emphasizing the impacts of contaminants on aquatic environments and potential risks to human health, it also relates to SDG 6 (Clean Water and Sanitation).
How Sex and Gender Impact Clinical Practice: An Evidence-Based Guide to Patient Care (Second Edition), 2026, pp 11-23
This chapter aligns with SDG 3 – Good Health and Well‑Being and SDG 5 – Gender Equality by demonstrating how gender‑informed communication strategies can improve clinician‑patient interactions, leading to better healthcare outcomes and more equitable, culturally aware treatment experiences for women and other gendered patient groups.
Olufunke Cofie, Adesola Olaleye, Birhanu Zemadim, Tafadzwanashe Mabhaudhi,
Chapter 4 - Current status of agricultural water management in Africa: progress, challenges, and opportunities,
Editor(s): Tafadzwanashe Mabhaudhi, Aidan Senzanje, Olufunke Cofie,
Agricultural Water Management in Africa,
Academic Press,
2026,
Pages 69-85,
ISBN 9780443215841,
https://doi.org/10.1016/B978-0-443-21584-1.00014-4.
The article directly connects agricultural water management (AWM) to SDG 2 (Zero Hunger), emphasizing that effective water management is crucial for achieving food security and agricultural transformation in Africa. The policy agenda outlined aligns with both Agenda 2063 and SDG 2, highlighting how accelerated, context-specific AWM can unlock substantial gains in food security, climate resilience, and rural livelihoods. The connection is reinforced through specific targets mentioned in the introduction, where water management is explicitly integrated into five of the six CAADP strategic objectives, supporting goals like 45% increase in agricultural output and 50% reduction in losses. Additionally, the AU's Agenda 2063 aims to enhance water productivity by 60%, capture 10% of rainwater for productive use, and recycle 10% of wastewater, directly supporting sustainable development through improved resource management.
Aquatic Waste Valorization: Innovative Approaches and Sustainable Strategies: 2026, Pages 29-52
This chapter aligns with UN Sustainable Development Goal 6 (Clean Water and Sanitation) and Goal 14 (Life Below Water) because it highlights how valorizing aquatic waste can reduce water pollution and protect aquatic ecosystems.
Mohamed Tawfik, Maha Al-Zu’bi, Youssef Brouziyne,
Chapter 2 - The transformative role of treated wastewater in North Africa: lessons learned and future directions,
Editor(s): Tafadzwanashe Mabhaudhi, Aidan Senzanje, Olufunke Cofie,
Agricultural Water Management in Africa,
Academic Press,
2026,
Pages 21-40,
ISBN 9780443215841,
https://doi.org/10.1016/B978-0-443-21584-1.00003-X.
The article directly supports SDG 6 (Clean Water and Sanitation) by demonstrating how treated wastewater can provide sustainable water solutions for agriculture in water-scarce North African countries. It also contributes to SDG 2 (Zero Hunger) by addressing food security challenges through innovative water management strategies that sustain agricultural production despite increasing water scarcity.
Karuppannan Iswarya, Ulaganathan Arisekar, Rajendran Shalini, Balasubramanian Sivaraman, Shanmugam Sundhar, Balamanikandan Vijayakumar, Antony J. Prabhu Philips,
Chapter 1 - Overview of aquatic food industry waste: challenges, opportunities, and sustainable valorization,
Editor(s): Piyush Kashyap, Tanmay Sarkar, Sajid Maqsood,
Aquatic Waste Valorization,
Academic Press,
2026,
Pages 3-27,
ISBN 9780443440274,
https://doi.org/10.1016/B978-0-443-44027-4.00013-5.
This chapter aligns with UN Sustainable Development Goal 6 (Clean Water and Sanitation) because it addresses the environmental impacts of aquatic food industry waste and explores sustainable strategies to reduce pollution and protect water resources.
Agricultural Water Management in Africa: Lessons Learned and Future Directions, 2026, pages 261-277
The article is closely linked to five key SDGs through its emphasis on gender equality and social inclusion (GESI) in agricultural water management. SDG 2 (Zero Hunger) highlights the critical role women play in food production and food security, underscoring the importance of ensuring equal access to water resources. SDG 5 (Gender Equality) focuses on reducing gender disparities, including unequal access to water resources and irrigation technologies. SDG 6 (Clean Water and Sanitation) calls for gender‑responsive approaches to water management. SDG 10 (Reduced Inequalities) stresses the need to ensure that marginalized groups, such as women and smallholder farmers, have equal rights to land and water resources. SDG 13 (Climate Action) advocates for integrating gender‑sensitive strategies into climate adaptation efforts related to agricultural water management. By aligning GESI principles with these SDGs, the article illustrates how inclusive approaches to agricultural water management can promote sustainable practices that alleviate poverty, strengthen food security, and support environmental sustainability, while also advancing social justice.
Agricultural Water Management in Africa: Lessons Learned and Future Directions, 2026, pages 279-299
The research strongly aligns with SDG 5 (Gender Equality) through its focus on women's empowerment in agricultural decision-making and economic participation. The study also connects to SDG 1 (No Poverty) by demonstrating how agricultural innovations and water management have contributed to poverty reduction and economic opportunities for marginalized groups, particularly women. The circular economy model described, where women engage in rice production while men focus on vegetables, creates sustainable livelihoods that support both gender equality and poverty alleviation goals. Finally, the article strongly connects to SDG 6 (Clean Water and Sanitation) through its focus on water management innovations and infrastructure development.
