Abstract
The relationship between water, energy, food, and the environment has piqued the interest of the global community due to the critical interdependence of these resources for long-term development. This article investigates research within the field of the quadruple nexus. Data from Scopus documents, with the keywords “water, energy, food, and environment” from 2011 to 2022, were processed and analyzed. Further research revealed that scientific exploration of the water-energy-food-environment relationship is rapidly expanding. The Scopus database was used to extract information about countries, institutions, highly cited publications, keywords, hot topics, and future research trends for this study. Additionally, the VOSviewer bibliometric software was employed to evaluate the scientific citations in this article. The results indicated that the USA, compared to other nations, publishes a larger quantity of articles in this field. Recently, China, India, and Middle Eastern countries have garnered significant attention and have been extensively researched. The Philippines, Finland, and Iran have also emerged among the top nations publishing recent articles on the water-energy-food-environment nexus (WEFEN). This article attempts to study the bibliography on the WEFEN connection, identify popular topics, and discern the fields of future studies in this discussion. Furthermore, it investigates the effects of economic and social factors as well as the impact of the COVID-19 pandemic on this quadruple nexus.
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Datasets analyzed during the current study are available and can be given following a reasonable request from the corresponding author.
References
Abbott M, Bazilian M, Egel D, Willis HH (2017) Examining the food–energy–water and conflict nexus. Curr Opin Chem Eng 18:55–60
Abdi H, Shahbazitabar M, Mohammadi-Ivatloo B (2020) Food, energy and water nexus: a brief review of definitions, research, and challenges. Inventions 5(4):56
Akram R, Fahad S, Hashmi MZ, Wahid A, Adnan M, Mubeen M . . . Abbas M (2019) Trends of electronic waste pollution and its impact on the global environment and ecosystem. Environ Sci Pollut Res 26:16923–16938
Allouche J, Middleton C, Gyawali D (2015) Technical veil, hidden politics: interrogating the power linkages behind the nexus. Water Alternat 8(1)
Al-Solaimani SG, Alghabari F, Ihsan MZ, Fahad S (2017) Water deficit irrigation and nitrogen response of Sudan grass under arid land drip irrigation conditions. Irrig Drain 66(3):365–376
Armfield NR, Edirippulige S, Caffery LJ, Bradford NK, Grey JW, Smith AC (2014) Telemedicine–a bibliometric and content analysis of 17,932 publication records. Int J Med Inform 83(10):715–725
Beekma J, Bird J, Mersha AN, Reinhard S, Prathapar SA, Rasul G . . . Perry C (2021) Enabling policy environment for water, food and energy security. Irrig Drain 70(3):392–409
Brunton G, Oliver S, Thomas J (2020) Innovations in framework synthesis as a systematic review method. Res Synth Methods 11(3):316–330
Carravetta A, Del Giudice G, Fecarotta O, Gallagher J, Cristina Morani M, Ramos HM (2022) Potential energy, economic, and environmental impacts of hydro power pressure reduction on the water-energy-food nexus. J Water Resour Plan Manag 148(5):04022012
Chamas Z, Abou Najm M, Al-Hindi M, Yassine A, Khattar R (2021) Sustainable resource optimization under water-energy-food-carbon nexus. J Clean Prod 278:123894
Chang Y, Li G, Yao Y, Zhang L, Yu C (2016) Quantifying the water-energy-food nexus: current status and trends. Energies 9(2):65
Chen C-Y, Wang S-W, Kim H, Pan S-Y, Fan C, Lin YJ (2021) Non-conventional water reuse in agriculture: a circular water economy. Water Res 199:117193
Correa-Cano M, Salmoral G, Rey D, Knox JW, Graves A, Melo O . . . Johnson C (2022) A novel modelling toolkit for unpacking the water-energy-food-environment (WEFE) nexus of agricultural development. Renew Sustain Energy Rev 159:112182
Dai J, Wu S, Han G, Weinberg J, Xie X, Wu X . . . Yang Q (2018) Water-energy nexus: a review of methods and tools for macro-assessment. Appl Energy 210:393–408
De Amorim WS, Valduga IB, Ribeiro JMP, Williamson VG, Krauser GE, Magtoto MK, de Andrade JBSO (2018) The nexus between water, energy, and food in the context of the global risks: an analysis of the interactions between food, water, and energy security. Environ Impact Assess Rev 72:1–11
Del Borghi A, Tacchino V, Moreschi L, Matarazzo A, Gallo M, Vazquez DA (2022) Environmental assessment of vegetable crops towards the water-energy-food nexus: a combination of precision agriculture and life cycle assessment. Ecol Ind 140:109015
Desa UN (2011) World population prospects: the 2010 revision, highlights and advance tables. United Nations
Elagib NA, Gayoum Saad SA, Basheer M, Rahma AE, Gore EDL (2021) Exploring the urban water-energy-food nexus under environmental hazards within the Nile. Stoch Environ Res Risk Assess 35(1):21–41
Estelaji F, Naseri A, Zahedi R (2022) Evaluation of the performance of vital services in urban crisis management. Adv Environ Eng Res 3(4):1–19
Estelaji F, Aghajari AA, Zahedi R (2023) Flood zoning and developing strategies to increase resilience against floods with a crisis management approach. Asian Rev Environ Earth Sci 10(1):14–27
Flammini A, Puri M, Pluschke L, Dubois O (2014) Walking the nexus talk: assessing the water-energy-food nexus in the context of the sustainable energy for all initiative. Fao. Environment and Natural Resources Working Paper No. 58
Gathala MK, Laing AM, Tiwari TP, Timsina J, Islam MS, Chowdhury AK . . . Shrestha R (2020) Enabling smallholder farmers to sustainably improve their food, energy and water nexus while achieving environmental and economic benefits. Renew Sustain Energy Rev:120:109645
Gebre SL, Van Orshoven J, Cattrysse D (2023) Optimizing the combined allocation of land and water to agriculture in the Omo-Gibe River basin considering the water-energy-food-nexus and environmental constraints. Land 12(2):412
Gitifar S, Zahedi R, Ziaie S, Mirzaei AM, Forootan MM (2024) Review of different vertical axis wind turbine modeling methods. Future Energy 3(1):23–33
Healy RW, Alley WM, Engle MA, McMahon PB, Bales JD (2015) The water-energy nexus: an earth science perspective. US geological survey circular(1407)
Howe P (2019) The triple nexus: a potential approach to supporting the achievement of the Sustainable Development Goals? World Dev 124:104629
Huq ME, Fahad S, Shao Z, Sarven MS, Khan IA, Alam M, Saud S (2020) Arsenic in a groundwater environment in Bangladesh: occurrence and mobilization. J Environ Manag 262:110318
Jabran K, Hussain M, Fahad S, Farooq M, Bajwa AA, Alharrby H, Nasim W (2016) Economic assessment of different mulches in conventional and water-saving rice production systems. Environ Sci Pollut Res 23:9156–9163
Khan MR, Wahab S, Qazi I, Ayub M, Muhammad A, Uddin Z . . . Noor M (2017) Effect of calcium fortification on whole wheat flour based leavened and unleavened breads by utilizing food industrial wastes. Asian J Chem 29(2)
Khazaee M, Zahedi R, Faryadras R, Ahmadi A (2022) Assessment of renewable energy production capacity of Asian countries: a review. New Energy Exploit Appl 1(2):25–41
Li M, Singh VP, Fu Q, Liu D, Li T, Zhou Y (2021a) Optimization of agricultural water–food–energy nexus in a random environment: an integrated modelling approach. Stoch Environ Res Risk Assess 35(1):3–19
Li S, Cai X, Emaminejad SA, Juneja A, Niroula S, Oh S . . . John S (2021b) Developing an integrated technology-environment-economics model to simulate food-energy-water systems in Corn Belt watersheds. Environ Model Softw 143:105083
Li M, Zhao L, Zhang C, Liu Y, Fu Q (2022) Optimization of agricultural resources in water-energy-food nexus in complex environment: a perspective on multienergy coordination. Energy Convers Manag 258:115537
Lin Y-P, Hong N-M, Chiang L-C, Liu Y-L, Chu H-J (2012) Adaptation of land-use demands to the impact of climate change on the hydrological processes of an urbanized watershed. Int J Environ Res Public Health 9(11):4083–4102
Lin Y-P, Mukhtar H, Huang K-T, Petway JR, Lin C-M, Chou C-F, Liao S-W (2020) Real-time identification of irrigation water pollution sources and pathways with a wireless sensor network and blockchain framework. Sensors 20(13):3634
Liu J, Yang H, Cudennec C, Gain AK, Hoff H, Lawford R . . . Zheng C (2017) Challenges in operationalizing the water–energy–food nexus. Hydrol Sci J 62(11):1714–1720
López-Illescas C, de Moya-Anegón F, Moed HF (2008) Coverage and citation impact of oncological journals in the Web of Science and Scopus. J Informet 2(4):304–316
Miralles-Wilhelm F (2016) Development and application of integrative modeling tools in support of food-energy-water nexus planning—a research agenda. J Environ Stud Sci 6(1):3–10
Mirjalili MA, Aslani A, Zahedi R, Soleimani M (2023) A comparative study of machine learning and deep learning methods for energy balance prediction in a hybrid building-renewable energy system. Sustain Energy Res 10(1):8
Mirzaei A, Abdeshahi A, Azarm H, Naghavi S (2022) New design of water-energy-food-environment nexus for sustainable agricultural management. Stoch Environ Res Risk Assess 36(7):1861–1874
Mirzavand H, Aslani A, Zahedi R (2022) Environmental impact and damage assessment of the natural gas pipeline: case study of Iran. Process Saf Environ 164:794–806
Mohtar RH, Lawford R (2016) Present and future of the water-energy-food nexus and the role of the community of practice. J Environ Stud Sci 6(1):192–199
Mukhtar H, Wunderlich RF, Petway JR, Lin Y-P (2019) Uncertainty propagation in crop adaptation responses to climate change: a modelling perspective. In (Vol. 6, pp. 115): MDPI
Mulyawati IB, Ramadhan DF (2021) Bibliometric and visualized analysis of scientific publications on geotechnics fields. ASEAN J Sci Eng Educ 1(1):37–46
Nasrollahi H, Shirazizadeh R, Shirmohammadi R, Pourali O, Amidpour M (2021) Unraveling the water-energy-food-environment nexus for climate change adaptation in Iran: Urmia Lake Basin case-study. Water 13(9):1282
Opejin AK, Aggarwal RM, White DD, Jones JL, Maciejewski R, Mascaro G, Sarjoughian HS (2020) A bibliometric analysis of food-energy-water nexus literature. Sustainability 12(3):1112
Proctor K, Tabatabaie SM, Murthy GS (2021) Gateway to the perspectives of the food-energy-water nexus. Sci Total Environ 764:142852
Qi Y, Farnoosh A, Lin L, Liu H (2022) Coupling coordination analysis of China’s provincial water-energy-food nexus. Environ Sci Pollut Res 29(16):23303–23313
Rahman A, Farrok O, Haque MM (2022) Environmental impact of renewable energy source based electrical power plants: solar, wind, hydroelectric, biomass, geothermal, tidal, ocean, and osmotic. Renew Sustain Energy Rev 161:112279
Rasul G (2014) Food, water, and energy security in South Asia: a nexus perspective from the Hindu Kush Himalayan region☆. Environ Sci Policy 39:35–48
Rasul G, Sharma B (2016) The nexus approach to water–energy–food security: an option for adaptation to climate change. Clim Policy 16(6):682–702
Romero-Lankao P, McPhearson T, Davidson DJ (2017) The food-energy-water nexus and urban complexity. Nat Clim Chang 7(4):233–235
Sánchez AD, Del Río M, d. l. C., & García, J. Á. (2017) Bibliometric analysis of publications on wine tourism in the databases Scopus and WoS. Eur Res Manag Bus Econ 23(1):8–15
Scoppola M (2022) Agriculture, food and global value chains: issues, methods and challenges. Bio-Based Appl Econ 11(2):91–92
Seidou O, Ringler C, Kalcic S, Ferrini L, Ramani TA, Guero A (2021) A semi-qualitative approach to the operationalization of the food–environment–energy–water (FE2W) nexus concept for infrastructure planning: a case study of the Niger Basin. Water Int 46(5):744–770
Sharmina M, Hoolohan C, Bows-Larkin A, Burgess P, Colwill J, Gilbert P . . . Anderson K (2015) The nexus in a changing climate: a critique of competing demands for UK land. In: Think Piece Series Paper
Simpson GB, Jewitt GP (2019) The development of the water-energy-food nexus as a framework for achieving resource security: a review. Front Environ Sci 7:8
Staupe-Delgado R (2020) The water–energy–food–environmental security nexus: moving the debate forward. Environ Dev Sustain 22(7):6131–6147
Van Vuuren D, Nakicenovic N, Riahi K, Brew-Hammond A, Kammen D, Modi V . . . Smith K (2012) An energy vision: the transformation towards sustainability—interconnected challenges and solutions. Curr Opin Environ Sustain 4(1):18–34
Wahid F, Sharif M, Fahad S, Adnan M, Khan IA, Aksoy E . . . Saeed M (2019) Arbuscular mycorrhizal fungi improve the growth and phosphorus uptake of mung bean plants fertilized with composted rock phosphate fed dung in alkaline soil environment. J Plant Nutr 42(15):1760–1769
Wang Q, Su M (2020) Integrating blockchain technology into the energy sector—from theory of blockchain to research and application of energy blockchain. Comput Sci Rev 37:100275
Wang Q, Huang R, Li R (2022a) Impact of the COVID-19 pandemic on research on marine plastic pollution–a bibliometric-based assessment. Mar Policy 146:105285
Wang Q, Huang R, Li R (2022b) Towards smart energy systems–a survey about the impact of COVID-19 pandemic on renewable energy research. Energy Strat Rev 41:100845
Wang Q, Zhang M, Li R (2022c) The COVID-19 pandemic reshapes the plastic pollution research–a comparative analysis of plastic pollution research before and during the pandemic. Environ Res 208:112634
Wang X, Wong YD, Chen T, Yuen KF (2023) Consumer logistics in contemporary shopping: a synthesised review. Transp Rev 43(3):502–532
Xiong J, Li Y, Yang Y (2022) Study on food-energy-water nexus and synergistic control of tourism in Beijing. Pol J Environ Stud 31(4)
Yoon PR, Lee S-H, Choi J-Y, Yoo S-H, Hur S-O (2022) Analysis of climate change impact on resource intensity and carbon emissions in protected farming systems using water-energy-food-carbon nexus. Resour Conserv Recycl 184:106394
Yue Q, Guo P (2021) Managing agricultural water-energy-food-environment nexus considering water footprint and carbon footprint under uncertainty. Agric Water Manag 252:106899
Zahedi R, Daneshgar S, Mohammad Mirzaei A, Pourrahmani H (2023) Free cooling in a building: the computational simulation using phase change material. Paper presented at the 243rd ECS Meeting with the 18th International Symposium on Solid Oxide Fuel Cells (SOFC-XVIII)
Zhang C, Chen X, Li Y, Ding W, Fu G (2018) Water-energy-food nexus: concepts, questions and methodologies. J Clean Prod 195:625–639
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All authors contributed to the study conception and design. Material preparation, data collection, and analysis were performed by Armin Tayefeh and Rahim Zahedi. The first draft of the manuscript was written by Mahmoud Abdous and Rahim Zahedi, and all authors commented on previous versions of the manuscript. Alireza Aslani and Mohammad Mahdi Zolfagharzadeh supervised the manuscript. All authors read and approved the final manuscript.
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Tayefeh, A., Abdous, M., Zahedi, R. et al. Advanced bibliometric analysis on water, energy, food, and environmental nexus (WEFEN). Environ Sci Pollut Res 30, 103556–103575 (2023). https://doi.org/10.1007/s11356-023-29379-8
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DOI: https://doi.org/10.1007/s11356-023-29379-8