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Achieving Sustainability in Nigerian Households: Investigating Factors Impacting Energy Efficiency Practices

Year 2023, Volume: 8 Issue: 3, 180 - 191, 03.10.2023
https://doi.org/10.47481/jscmt.1261384

Abstract

The looming global energy crisis of the 21st century is predicted to worsen as building energy consumption is expected to rise by 50% by 2060. Investing in energy-efficient technologies and reducing carbon emissions is essential to combat this crisis. To this end, this paper delves into the complex issue of energy-efficient building practices in Nigerian households and how they can help curb carbon emissions. Using a statistical method known as the Relative Impor- tance Index (RII), we analyzed nine key factors that influence a building’s energy efficiency. The research revealed that government oversight, support, and financial and technical assis- tance are crucial for achieving household energy efficiency. It also highlights the significance of addressing the energy crisis in Nigeria through the development, implementation, and ad- aptation of energy-efficient building practices.

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Project Number

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References

  • Oyedepo, S.O. (2012) Energy Efficiency and Conservation Measures: Tools for Sustainable Energy Development in Nigeria. International Journal of Energy Engineering, 2, 86-98.
  • IEA. Buildings: A source of enormous untapped efficiency potential, June 11, 2020. IEA. https://www.iea.org/topics/buildings.
  • Lu N., Taylor T., Jiang W., Correia, J., Leung, L. R., & Wong, P. C. The temperature sensitivity of the residential load and commercial building load. 2009 IEEE Power & Energy Society General Meeting, Calgary, AB, Canada, 2009. [CrossRef]
  • Wen, Q., Liu, G., Wu, W., & Liao S. (2020). Genetic algorithm-based operation strategy optimization and multi-criteria evaluation of distributed energy systems for commercial buildings. Energy Conversation Management, 226, Article 113529. [CrossRef]
  • IEA. World Energy Outlook 2020 shows how the response to the Covid crisis can reshape the future of energy. IEA. https://www.iea.org/news/world-energy-outlook-2020-shows-how-the-response-to-the-covid-crisis-can-reshape-the-future-of-energy
  • Ma, M., Ma, X., Cai, W., & Cai, W. (2020). Low carbon roadmap of the residential building sector in China: Historical mitigation and prospective peak. Applied Energy, 27, Article 115247. [CrossRef]
  • Yang, C., Wang, X., Huang, M., Ding, S., & Ma, X. (2017). Design and simulation of gas turbine-based CCHP combined with solar and compressed air energy storage in a hotel building. Energy and Buildings 153, 412–420. [CrossRef]
  • Amasyali, K., & El-Gohary, N. M. (2018). A review of data-driven building energy consumption prediction studies. Renewable and Sustainable Energy Reviews 81, 1192–1205. [CrossRef]
  • Hong, T., Koo, C., Kim, J., Lee, M., & Jeong, K. (2015). A review on sustainable construction management strategies for monitoring, diagnosing, and retrofitting the building's dynamic energy performance: focused on the operation and maintenance phase. Applied Energy, 155, 671–707. [CrossRef]
  • Berardi, U. (2017). A cross-country comparison of the building energy consumption and their trends. Resource Conservation Recycle, 123, 230–241. [CrossRef]
  • Birol, F. (2020). Put clean energy at the heart of stimulus plans to counter the coronavirus crisis. The coronavirus is turning into an unprecedented international crisis, with serious repercussions for people's health and economic activity. IEA. https://www.iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-plans-to-counter-the-coronavirus-crisis
  • Hernandez, P., Oregi, X., Longo, S., & Cellura, M. (2019). Life-cycle assessment of buildings. In Handbook of Energy Efficiency in Buildings (pp. 207-261). Butterworth-Heinemann.
  • Bose, R. K. (2010). Energy efficient cities: assessment tools and benchmarking practices. The World Bank. http://documents1.worldbank.org/curated/en/602471468337215697/pdf/544330PUB0EPI01BOX0349415B01PUBLIC1.pdf. [CrossRef]
  • Ebinger, J., & Vergara, W. (2011). Climate impacts on energy systems, no. September 2016. [CrossRef]
  • Sousa, J. L., Martins, A. G., & Jorge, H. (2013). Dealing with the paradox of energy efficiency promotion by electric utilities. Energy, 57, 251–258. [CrossRef]
  • Sunarso, O., Widiasa, S. J., Budiyono, I. N., (2010). The effect of feed to inoculum ratio on biogas production rate from castle manure using rumen fluid as inoculums. International Journal of Science and Engineering, 1(2), 41-45. [CrossRef]
  • W. & H. Federal Ministry of Power. (2016). Building energy efficiency guidelines for Nigeria's federal ministry of power, works and housing. https://energypedia.info/images/c/c7/Building_Energy_Efficiency_Guideline_for_Nigeria_2016.pdf.
  • Labaran, Y. H., Mathur, V. S., Muhammad, S. U., Musa, A. A. (2022). Carbon footprint management: A review of construction industry. Cleaner Engineering and Technology, 9, 2022, Article 100531. [CrossRef]
  • Ley, K., Gaines, J., & Ghatikar, A. (2015). the Nigerian energy sector - an overview with a special emphasis on renewable energy, energy efficiency and rural electrification. Int. Zusammenarbeit GmbH. www.gopa-intec.de.
  • Craig, K. T. O., Verma, H., Iliyasu, Z., Mkanda, P., Touray, K. (2016). Role of serial polio seroprevalence studies in guiding implementation of the polio eradication initiative in Kano, Nigeria: 2011–2014. The Journal of Infectious Diseases, 213(3), 124–130. [CrossRef]
  • Koko, A. F., Wu, Y., Abubakar, G. A., Alabsi, A. A. N., Hamed, R., Bello, M. (2021). Thirty years of land use and land cover changes and their impact on urban climate: a study of Kano Metropolis, Nigeria. Land 10, Article 1106. [CrossRef]
  • Jibrin, A. M., Muhammad, N. Z., & Labaran, Y. H. (2020). Evaluation of factors responsible for variation order in civil engineering projects: A clients' perspective (a case study in Kano state, Nigeria). International Research Journal of Engineering and Technology (IRJET), 7(5), 1373-1377.
  • Shen, Z., Chen, A. (2020). Comprehensive relative importance analysis and its applications to high-dimensional gene expression data analysis. Knowledge-Based Systems, 203, Article 106120. [CrossRef]
  • Geissler, S., Österreicher, D., & Macharm, E. (2018). Transition towards energy efficiency: Developing the Nigerian building energy efficiency code. Sustain 10(8), 1–21. [CrossRef]
  • Abdul Majid, N. H, Hussaini, I. U. (2011). Housing design practice and energy efficiency consideration in Nigeria. Third International Conference on Applied Energy - 16-18 May 2011 - Perugia, Italy, 1459-1470. http://irep.iium.edu.my/29079/.
  • Martinez, K. E. (2008). Changing habits, lifestyles, and choices: the behaviours that drive feedback-induced energy savings, renewable and sustainable energy institute. University of Colorado 305 Flemming Boulder, CO 80309.
  • Creswell, J. W. (2009). Research design: qualitative, quantitative, and mixed methods approaches, 3rd edition. London: Sage.
  • Sekaran, U. (2005). Research methods for business: A skill building approach. 4th edition. India: John Wiley & Sons.
  • Akinbulire, T. O., Awosope, C. O. A & Oluseyi, P. O. (2007). Solving the technical problems facing electrical energy development in Nigeria. 3rd Annual Conference Research and Fair of the University of Lagos, Nigeria, December 3.
  • Akhator, E. P., Obanor, A. I., & Ezemonye, L. I. (2016). Electricity generation in Nigeria from municipal solid waste using the Swedish Waste-to-Energy Model. Journal of Applied Sciences and Environmental Management, 20(3), 635. [CrossRef]
  • Adeyemi, A. O. (2013). Electricity consumption and economic growth in Nigeria Journal of Business Management and Applied Economics, 2, 1–14.
  • Rabah, A. B., Baki, A. S., Hassan, L. G., Musa, M., Ibrahim, A. D. (2010). Production of biogas using abattoir waste at different retention times. Science World Journal 5, 1597–6343.
  • Odekanle, E. L., Odejobi, O. J., Dahunsi, S. O., & Akeredolu, F. A. (2020). Potential for cleaner energy recovery and electricity generation from Abattoir wastes in Nigeria. Energy Reports 6, 1262–1267. [CrossRef]
  • Olanipekun, B. A., & Adelakun, N. O. (2020). Assessment of renewable energy in Nigeria: challenges and benefits. International Journal Of Engineering Trends And Technology, 68(1), 64-67. [CrossRef]
  • Emovon, I., Samuel, O. D., Mgbemena, C. O., & Adeyeri, M. K. (2018). Electric power generation crisis in Nigeria: A review of causes and solutions. International Journal of Integrated Engineering, 10(1), 47-56. [CrossRef]
  • Festus, M. O., & Ogoegbunam, O. B. (2015). Energy crisis and its effects on national development: The need for environmental education in Nigeria. British Journal of Education, 3(1), 21-37.
  • Bell, E., & Bryman, A. (2007). The ethics of management research: an exploratory content analysis. British Journal of Management, 18(1), 63–77. [CrossRef]
  • The World Bank. (2023) Primary data collection. https://dimewiki.worldbank.org/Primary_Data_Collection
  • Ellram, L. M., Tate, W. L. (2016). The use of secondary data in purchasing and supply management (P/SM) research. Journal of Purchasing and Supply Management, 22(4), 250-254. [CrossRef]
  • Garth, A. (2008). Analyzing data using SPSS, Sheffield Hallam University. https://students.shu.ac.uk/lits/it/documents/pdf/analysing_data_using_spss.pdf
  • Azmy, A., Shane, J., & Shelley, M. (2012). Implementation of survey method in a construction team effectiveness study. Construction Research Congress 2012, 1471-1480. [CrossRef]
  • Ira H. Bernstein, Likert Scale Analysis. (2005). Kimberly Analysis, Editor of Social Measurement. Elsevier.
  • Tran, Q., Nazir, S., Nguyen T. H., Ho, N. K., Dinh, T. H., Nguyen, V. P., Nguyen, M. H., Phan, Q. K., Kieu, T. S. (2020). Empirical examination of factors influencing the adoption of green building technologies: the perspective of construction developers in developing economies. Sustainability, 12(19), 8067. [CrossRef]
  • Estache, A., & Kaufmann, M. (2011). Theory and evidence on the economics of energy efficiency. Lessons for the Belgian building sector. Reflets Et Perspectives De La Vie Économique, Tome L, 133-148. [CrossRef]
  • Adedayo, H. B., Adio, S., & Oboirien, B. O. (2021). Energy research in Nigeria: A bibliometric analysis. Energy Strategy Reviews, 34, Article 100629. [CrossRef]
  • Santamouris, M., Vasilakopoulou, K. (2021). Present and future energy consumption of buildings: Challenges and opportunities towards decarbonization. e-Prime - Advances in Electrical Engineering, Electronics and Energy, 1, Article 100002. [CrossRef]
  • Oyedepo, S.O. (2012). Energy and sustainable development in Nigeria: the way forward. Energy Sustain Society, 2, Article 15.
  • Kumssa, A., Mosha, A.C., Mbeche, I.M., Njeru, E.H.N. (2015). Climate change and urban development in Africa. Springer, Berlin, Heidelberg. [CrossRef]
  • Oyalowo, B., Ohiro, Y., Oginni, A. (2020). Barriers, drivers and prospects of the energy efficiency code in the Lagos real estate market. Earth and Environmental Science, 588, Article 022033. [CrossRef]
  • Abisuga, A. O., Okuntade, T. F. (2020). The Current State of Green Building Development in Nigerian Construction Industry: Policy and Implications. In: Gou, Z. (eds). Green Building in Developing Countries. Green Energy and Technology. Springer, Cham. [CrossRef]
  • Qin, Y., Xu, Z., Wang, X., Škare, M. (2022). Green energy adoption and its determinants: A bibliometric analysis. Renewable and Sustainable Energy Reviews, 153, Article 111780.
  • Painuly, J. (2001). Barriers to renewable energy penetration; a framework for analysis. Renewable Energy, 24(1), 73–89.
  • Thorne, S. (2008). Towards a framework of clean energy technology receptivity. Energy Policy, 36(8), 2831–2838. [CrossRef]
  • Bagaini, A., Colelli, F., Croci, E., & Molteni, T. (2020). Assessing the relevance of barriers to energy efficiency implementation in eight European countries' building and transport sectors. The Electricity Journal, 33(8), Article 106820. [CrossRef]
  • Doukas, H., Karakosta, C., & Psarras, J. (2009). RES technology transfer within the new climate regime: A "helicopter" view under the CDM. Renewable and Sustainable Energy Reviews, 13(5), 1138–1143. [CrossRef]
  • Karakosta, C., Doukas, H., & Psarras, J. (2010). Technology transfer through climate change: Setting a sustainable energy pattern. Renewable and Sustainable Energy Reviews, 14(6), 1546–1557.
  • Jagadeesh, A. (2000). Wind energy development in Tamil Nadu and Andhra Pradesh, India Institutional dynamics and barriers—A case study. Energy Policy, 28(3), 157-168.
  • Ravindranath, N. H., & Balachandra, P. (2009). Sustainable bioenergy for India: Technical, economic, and policy analysis. Energy, 34(8), 1003–1013. [CrossRef]

Achieving Sustainability in Nigerian Households: Investigating Factors Impacting Energy Efficiency Practices

Year 2023, Volume: 8 Issue: 3, 180 - 191, 03.10.2023
https://doi.org/10.47481/jscmt.1261384

Abstract

The looming global energy crisis of the 21st century is predicted to get even worse as building energy consumption is expected to rise by 50% by 2060. To combat this crisis, it is essential to invest in energy-efficient technologies and reduce carbon emissions. To this end, this paper delves into the complex issue of energy-efficient building practices in Nigerian households and how they can help curb the country's carbon emissions. Using a statistical method known as the Relative Importance Index (RII), we analyzed nine key factors that influence a building's energy efficiency. The research revealed that government oversight, support, and financial and technical assistance are crucial for achieving household energy efficiency. It also highlights the significance of addressing the energy crisis in Nigeria through the development, implementation, and adaptation of energy-efficient building practices.

Project Number

nil

References

  • Oyedepo, S.O. (2012) Energy Efficiency and Conservation Measures: Tools for Sustainable Energy Development in Nigeria. International Journal of Energy Engineering, 2, 86-98.
  • IEA. Buildings: A source of enormous untapped efficiency potential, June 11, 2020. IEA. https://www.iea.org/topics/buildings.
  • Lu N., Taylor T., Jiang W., Correia, J., Leung, L. R., & Wong, P. C. The temperature sensitivity of the residential load and commercial building load. 2009 IEEE Power & Energy Society General Meeting, Calgary, AB, Canada, 2009. [CrossRef]
  • Wen, Q., Liu, G., Wu, W., & Liao S. (2020). Genetic algorithm-based operation strategy optimization and multi-criteria evaluation of distributed energy systems for commercial buildings. Energy Conversation Management, 226, Article 113529. [CrossRef]
  • IEA. World Energy Outlook 2020 shows how the response to the Covid crisis can reshape the future of energy. IEA. https://www.iea.org/news/world-energy-outlook-2020-shows-how-the-response-to-the-covid-crisis-can-reshape-the-future-of-energy
  • Ma, M., Ma, X., Cai, W., & Cai, W. (2020). Low carbon roadmap of the residential building sector in China: Historical mitigation and prospective peak. Applied Energy, 27, Article 115247. [CrossRef]
  • Yang, C., Wang, X., Huang, M., Ding, S., & Ma, X. (2017). Design and simulation of gas turbine-based CCHP combined with solar and compressed air energy storage in a hotel building. Energy and Buildings 153, 412–420. [CrossRef]
  • Amasyali, K., & El-Gohary, N. M. (2018). A review of data-driven building energy consumption prediction studies. Renewable and Sustainable Energy Reviews 81, 1192–1205. [CrossRef]
  • Hong, T., Koo, C., Kim, J., Lee, M., & Jeong, K. (2015). A review on sustainable construction management strategies for monitoring, diagnosing, and retrofitting the building's dynamic energy performance: focused on the operation and maintenance phase. Applied Energy, 155, 671–707. [CrossRef]
  • Berardi, U. (2017). A cross-country comparison of the building energy consumption and their trends. Resource Conservation Recycle, 123, 230–241. [CrossRef]
  • Birol, F. (2020). Put clean energy at the heart of stimulus plans to counter the coronavirus crisis. The coronavirus is turning into an unprecedented international crisis, with serious repercussions for people's health and economic activity. IEA. https://www.iea.org/commentaries/put-clean-energy-at-the-heart-of-stimulus-plans-to-counter-the-coronavirus-crisis
  • Hernandez, P., Oregi, X., Longo, S., & Cellura, M. (2019). Life-cycle assessment of buildings. In Handbook of Energy Efficiency in Buildings (pp. 207-261). Butterworth-Heinemann.
  • Bose, R. K. (2010). Energy efficient cities: assessment tools and benchmarking practices. The World Bank. http://documents1.worldbank.org/curated/en/602471468337215697/pdf/544330PUB0EPI01BOX0349415B01PUBLIC1.pdf. [CrossRef]
  • Ebinger, J., & Vergara, W. (2011). Climate impacts on energy systems, no. September 2016. [CrossRef]
  • Sousa, J. L., Martins, A. G., & Jorge, H. (2013). Dealing with the paradox of energy efficiency promotion by electric utilities. Energy, 57, 251–258. [CrossRef]
  • Sunarso, O., Widiasa, S. J., Budiyono, I. N., (2010). The effect of feed to inoculum ratio on biogas production rate from castle manure using rumen fluid as inoculums. International Journal of Science and Engineering, 1(2), 41-45. [CrossRef]
  • W. & H. Federal Ministry of Power. (2016). Building energy efficiency guidelines for Nigeria's federal ministry of power, works and housing. https://energypedia.info/images/c/c7/Building_Energy_Efficiency_Guideline_for_Nigeria_2016.pdf.
  • Labaran, Y. H., Mathur, V. S., Muhammad, S. U., Musa, A. A. (2022). Carbon footprint management: A review of construction industry. Cleaner Engineering and Technology, 9, 2022, Article 100531. [CrossRef]
  • Ley, K., Gaines, J., & Ghatikar, A. (2015). the Nigerian energy sector - an overview with a special emphasis on renewable energy, energy efficiency and rural electrification. Int. Zusammenarbeit GmbH. www.gopa-intec.de.
  • Craig, K. T. O., Verma, H., Iliyasu, Z., Mkanda, P., Touray, K. (2016). Role of serial polio seroprevalence studies in guiding implementation of the polio eradication initiative in Kano, Nigeria: 2011–2014. The Journal of Infectious Diseases, 213(3), 124–130. [CrossRef]
  • Koko, A. F., Wu, Y., Abubakar, G. A., Alabsi, A. A. N., Hamed, R., Bello, M. (2021). Thirty years of land use and land cover changes and their impact on urban climate: a study of Kano Metropolis, Nigeria. Land 10, Article 1106. [CrossRef]
  • Jibrin, A. M., Muhammad, N. Z., & Labaran, Y. H. (2020). Evaluation of factors responsible for variation order in civil engineering projects: A clients' perspective (a case study in Kano state, Nigeria). International Research Journal of Engineering and Technology (IRJET), 7(5), 1373-1377.
  • Shen, Z., Chen, A. (2020). Comprehensive relative importance analysis and its applications to high-dimensional gene expression data analysis. Knowledge-Based Systems, 203, Article 106120. [CrossRef]
  • Geissler, S., Österreicher, D., & Macharm, E. (2018). Transition towards energy efficiency: Developing the Nigerian building energy efficiency code. Sustain 10(8), 1–21. [CrossRef]
  • Abdul Majid, N. H, Hussaini, I. U. (2011). Housing design practice and energy efficiency consideration in Nigeria. Third International Conference on Applied Energy - 16-18 May 2011 - Perugia, Italy, 1459-1470. http://irep.iium.edu.my/29079/.
  • Martinez, K. E. (2008). Changing habits, lifestyles, and choices: the behaviours that drive feedback-induced energy savings, renewable and sustainable energy institute. University of Colorado 305 Flemming Boulder, CO 80309.
  • Creswell, J. W. (2009). Research design: qualitative, quantitative, and mixed methods approaches, 3rd edition. London: Sage.
  • Sekaran, U. (2005). Research methods for business: A skill building approach. 4th edition. India: John Wiley & Sons.
  • Akinbulire, T. O., Awosope, C. O. A & Oluseyi, P. O. (2007). Solving the technical problems facing electrical energy development in Nigeria. 3rd Annual Conference Research and Fair of the University of Lagos, Nigeria, December 3.
  • Akhator, E. P., Obanor, A. I., & Ezemonye, L. I. (2016). Electricity generation in Nigeria from municipal solid waste using the Swedish Waste-to-Energy Model. Journal of Applied Sciences and Environmental Management, 20(3), 635. [CrossRef]
  • Adeyemi, A. O. (2013). Electricity consumption and economic growth in Nigeria Journal of Business Management and Applied Economics, 2, 1–14.
  • Rabah, A. B., Baki, A. S., Hassan, L. G., Musa, M., Ibrahim, A. D. (2010). Production of biogas using abattoir waste at different retention times. Science World Journal 5, 1597–6343.
  • Odekanle, E. L., Odejobi, O. J., Dahunsi, S. O., & Akeredolu, F. A. (2020). Potential for cleaner energy recovery and electricity generation from Abattoir wastes in Nigeria. Energy Reports 6, 1262–1267. [CrossRef]
  • Olanipekun, B. A., & Adelakun, N. O. (2020). Assessment of renewable energy in Nigeria: challenges and benefits. International Journal Of Engineering Trends And Technology, 68(1), 64-67. [CrossRef]
  • Emovon, I., Samuel, O. D., Mgbemena, C. O., & Adeyeri, M. K. (2018). Electric power generation crisis in Nigeria: A review of causes and solutions. International Journal of Integrated Engineering, 10(1), 47-56. [CrossRef]
  • Festus, M. O., & Ogoegbunam, O. B. (2015). Energy crisis and its effects on national development: The need for environmental education in Nigeria. British Journal of Education, 3(1), 21-37.
  • Bell, E., & Bryman, A. (2007). The ethics of management research: an exploratory content analysis. British Journal of Management, 18(1), 63–77. [CrossRef]
  • The World Bank. (2023) Primary data collection. https://dimewiki.worldbank.org/Primary_Data_Collection
  • Ellram, L. M., Tate, W. L. (2016). The use of secondary data in purchasing and supply management (P/SM) research. Journal of Purchasing and Supply Management, 22(4), 250-254. [CrossRef]
  • Garth, A. (2008). Analyzing data using SPSS, Sheffield Hallam University. https://students.shu.ac.uk/lits/it/documents/pdf/analysing_data_using_spss.pdf
  • Azmy, A., Shane, J., & Shelley, M. (2012). Implementation of survey method in a construction team effectiveness study. Construction Research Congress 2012, 1471-1480. [CrossRef]
  • Ira H. Bernstein, Likert Scale Analysis. (2005). Kimberly Analysis, Editor of Social Measurement. Elsevier.
  • Tran, Q., Nazir, S., Nguyen T. H., Ho, N. K., Dinh, T. H., Nguyen, V. P., Nguyen, M. H., Phan, Q. K., Kieu, T. S. (2020). Empirical examination of factors influencing the adoption of green building technologies: the perspective of construction developers in developing economies. Sustainability, 12(19), 8067. [CrossRef]
  • Estache, A., & Kaufmann, M. (2011). Theory and evidence on the economics of energy efficiency. Lessons for the Belgian building sector. Reflets Et Perspectives De La Vie Économique, Tome L, 133-148. [CrossRef]
  • Adedayo, H. B., Adio, S., & Oboirien, B. O. (2021). Energy research in Nigeria: A bibliometric analysis. Energy Strategy Reviews, 34, Article 100629. [CrossRef]
  • Santamouris, M., Vasilakopoulou, K. (2021). Present and future energy consumption of buildings: Challenges and opportunities towards decarbonization. e-Prime - Advances in Electrical Engineering, Electronics and Energy, 1, Article 100002. [CrossRef]
  • Oyedepo, S.O. (2012). Energy and sustainable development in Nigeria: the way forward. Energy Sustain Society, 2, Article 15.
  • Kumssa, A., Mosha, A.C., Mbeche, I.M., Njeru, E.H.N. (2015). Climate change and urban development in Africa. Springer, Berlin, Heidelberg. [CrossRef]
  • Oyalowo, B., Ohiro, Y., Oginni, A. (2020). Barriers, drivers and prospects of the energy efficiency code in the Lagos real estate market. Earth and Environmental Science, 588, Article 022033. [CrossRef]
  • Abisuga, A. O., Okuntade, T. F. (2020). The Current State of Green Building Development in Nigerian Construction Industry: Policy and Implications. In: Gou, Z. (eds). Green Building in Developing Countries. Green Energy and Technology. Springer, Cham. [CrossRef]
  • Qin, Y., Xu, Z., Wang, X., Škare, M. (2022). Green energy adoption and its determinants: A bibliometric analysis. Renewable and Sustainable Energy Reviews, 153, Article 111780.
  • Painuly, J. (2001). Barriers to renewable energy penetration; a framework for analysis. Renewable Energy, 24(1), 73–89.
  • Thorne, S. (2008). Towards a framework of clean energy technology receptivity. Energy Policy, 36(8), 2831–2838. [CrossRef]
  • Bagaini, A., Colelli, F., Croci, E., & Molteni, T. (2020). Assessing the relevance of barriers to energy efficiency implementation in eight European countries' building and transport sectors. The Electricity Journal, 33(8), Article 106820. [CrossRef]
  • Doukas, H., Karakosta, C., & Psarras, J. (2009). RES technology transfer within the new climate regime: A "helicopter" view under the CDM. Renewable and Sustainable Energy Reviews, 13(5), 1138–1143. [CrossRef]
  • Karakosta, C., Doukas, H., & Psarras, J. (2010). Technology transfer through climate change: Setting a sustainable energy pattern. Renewable and Sustainable Energy Reviews, 14(6), 1546–1557.
  • Jagadeesh, A. (2000). Wind energy development in Tamil Nadu and Andhra Pradesh, India Institutional dynamics and barriers—A case study. Energy Policy, 28(3), 157-168.
  • Ravindranath, N. H., & Balachandra, P. (2009). Sustainable bioenergy for India: Technical, economic, and policy analysis. Energy, 34(8), 1003–1013. [CrossRef]
There are 58 citations in total.

Details

Primary Language English
Subjects Civil Engineering
Journal Section Research Articles
Authors

Hussaini Mato 0000-0003-1878-2939

Yahaya Hassan Labaran 0000-0002-9166-0279

Dipanjan Mukherjee This is me

Gaurav Saini This is me

Mahmoud Murtala Farouq This is me

Project Number nil
Early Pub Date September 30, 2023
Publication Date October 3, 2023
Submission Date March 7, 2023
Acceptance Date August 19, 2023
Published in Issue Year 2023 Volume: 8 Issue: 3

Cite

APA Mato, H., Labaran, Y. H., Mukherjee, D., Saini, G., et al. (2023). Achieving Sustainability in Nigerian Households: Investigating Factors Impacting Energy Efficiency Practices. Journal of Sustainable Construction Materials and Technologies, 8(3), 180-191. https://doi.org/10.47481/jscmt.1261384

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E-mail: jscmt@yildiz.edu.tr