Abstract
Sustainable buildings have an important role in achieving sustainable development by improving energy utilization and environmental performance. Buildings are considered as the biggest single contributor to world energy consumption and greenhouse gas emissions. In Saudi Arabia, the significance of the building sector can be described on the basis of per capita electricity consumption, per capita carbon dioxide emissions, and the increasing number of buildings because of economic and population growth. Therefore, the country should consider establishing energy-efficient buildings to promote sustainable development. Efforts in developing energy-efficient technologies should increase for the national energy policy. This article comprehensively describes the current challenges and opportunities of energy consumption and various energy conservation options that are viable for the Saudi building sector. Current policy efforts for improving energy efficiency in Saudi buildings have been analyzed to enhance the sustainable development in the country. The study reveals that the energy conservation policy of the country has fairly improved in the past decades. However, the country has to focus on this area and perform urgent measures to adopt energy-efficient technologies in the building sector.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abdul Mujeebu, M., & Alshamrania, O. S. (2015). A review of solar energy exploration and utilization in Saudi buildings. International Journal of Advanced Thermofluid Research, 1(1), 70–85.
Akbar, J. (1986). Architectural education in the Kingdom of Saudi Arabia. In: Architectural education in the Islamic world. Paper presented at The Aga Khan Award for Architecture. Singapore: Concept Media Ltd.
Al-Homoud, M. S. (1997a). Optimum thermal design of office buildings. International Journal of Energy Research, 21(10), 941–957. doi:10.1002/(SICI)1099-114X(199708)21:10<941.
Al-Homoud, M. S. (1997b). Optimum thermal design of air-conditioned residential buildings. Building and Environment, 32(3), 203–210.
Al-Homoud, M. S. (2001). Computer-aided building energy analysis techniques. Building and Environment, 36(4), 421–433. doi:10.1016/S0360-1323(00)00026-3.
Al Surf, M. S., Susilawati, C., & Trigunarsyah, B. (2014). The role of the Saudi government and the Saudi building code in implementing sustainable housing construction in Saudi Arabia. Paper presented at the 20th Annual Pacific-Rim Real Estate Society Conference, New Zealand,
Almasoud, A. H., & Gandayh, H. M. (2015). Future of solar energy in Saudi Arabia. Journal of King Saud University - Engineering Sciences, 27(2), 153–157. doi:10.1016/j.jksues.2014.03.007.
Almatawa, M. S., Elmualim, A. A., & Essah, E. A. (2013). Passive and active hybrid approach to building design in Saudi Arabia. WIT Transactions on Ecology and the Environment, 165, 163–174.
Alnaser, N. W., Flanagan, R., & Alnaser, W. E. (2008). Model for calculating the sustainable building index (SBI) in the kingdom of Bahrain. Energy and Buildings, 40(1), 2037–2043. doi:10.1016/j.enbuild.2008.05.015.
Alowaidh, M., & Alnutifi, A. (2010). Technology-based improvement for KSA energy intensity. Internal Report: Saudi Aramco.
Alrashed, F., & Asif, M. (2012a). Challenges facing the application of zero-energy homes in Saudi Arabia: construction industry and user perspective. Glasgow: Paper presented at the in ZEMCH 2012 International Conference.
Alrashed, F., & Asif, M. (2012b). Prospects of renewable energy to promote zero-energy residential buildings in the KSA. Energy Procedia, 18, 1096–1105. doi:10.1016/j.egypro.2012.05.124.
Alrashed, F., & Asif, M. (2014). Saudi building industry’s views on sustainability in buildings: questionnaire survey. Energy Procedia, 62, 382–390. doi:10.1016/j.egypro.2014.12.400.
Alyousef, Y., & Abu-ebid, M. (2012)(Eds.). Energy efficiency initiatives for Saudi Arabia on supply and demand sides (Energy efficiency—a bridge to low carbon economy): InTech.
Anon. (1987). Our common future, world commission on environment and development. Oxford: Oxford University Press.
Bourland, B., & Gamble, P. (2011). Saudi Arabia’s coming oil and fiscal challenge. (pp. 3–24). Jadwa Investment.
CDSI (2014). Statistical yearbook. In C. D. o. S. Information (Ed.), (Vol. 50). Riyadh, KSA: CDSI.
Clarke, J. A. (1993). Assessing building performance by simulation. Building and Environment, 28(4), 419–427. doi:10.1016/0360-1323(93)90019-Y.
Deloitte. (2010). GCC powers of construction 2010: construction sector overview (p. 25). New York: Deloitte & Touche.
Dincer, I., & Rosen, M. A. (1998). A worldwide perspective on energy, environment and sustainable development. International Journal of Energy Research, 22(15), 1305–1321. doi:10.1002/(SICI)1099-114X(199812)22:15<1305::AID-ER417>3.0.CO;2-H.
EAA. (2002). Electricity growth and development in the Kingdom of Saudi Arabia. Riyadh, KSA: Electrical Affairs Agency: Ministry of Industry and Electricity.
ECRA. (2007). Annual statistical booklet for electricity & seawater desalination industries. KSA: Electricity and Cogeneration Regulatory Authority.
ECRA. (2014). Annual statistical booklet for electricity & seawater desalination industries. KSA: Electricity and Cogeneration Regulatory Authority.
EIA (2014). Independent statistics and analysis: Annual Energy Outlook 2014 early release overview. Available: http://www.eia.gov/forecasts/aeo/er/. Accessed 26 Dec 2015.
Ezeabasili, N. (2009). Legal mechanism for achieving environmental sustainability in Nigeria 2009. African Research Review, 3(2), 369–380.
Fawaz, D. (2014). A greener lifestyle shapes the Middle East. Arab Construction World (ACW), 32(10), 20–22.
GCS (2016). Official map of the kingdom, General Commission for Survey. http://www.gcs.gov.sa/Products/Topographic-Products/Official-Map-Of-The-Kingdom-Of-Saudi-Arabia.aspx: General Commission for Survey.
Gopal, A. R., Leventis, G., Phadke, A., & de la Rue du Can, S. (2014). Self-financed efficiency incentives: case study of Mexico. Energy Efficiency, 7(5), 865–877. doi:10.1007/s12053-014-9263-9.
Hepbasli, A., & Alsuhaibani, Z. (2011). A key review on present status and future directions of solar energy studies and applications in Saudi Arabia. Renewable and Sustainable Energy Reviews, 15(9), 5021–5050. doi:10.1016/j.rser.2011.07.052.
Hussin, J., Rahman, I. A., & Memon, A. (2013). The way forward in sustainable construction: issues and challenges. International Journal of Advances in Applied Sciences, 2(1), 31–42.
IEA (2012). Electricity information. The International Energy Agency Statistics, http://www.iea.org/ .
KAUST (2014). Appraisal and evaluation of energy utilization and efficiency in the Kingdom of Saudi Arabia. Industry Collaboration Program, KAUST University, Volume (1).
Krishna, L. V. (2014). Long term temperature trends in four different climatic zones of Saudi Arabia. International Journal of Applied Science and Technology, 4(5), 233–242.
KSA, G. (2016). Vision 2030. Council of Economic and Development Affairs, 84.
Lahn, G., & Stevens, P. (2011). Burning oil to keep cool: the hidden energy crisis in Saudi Arabia. London: Royal Institute of International Affairs.
Matar, W. (2016). Beyond the end-consumer: how would improvements in residential energy efficiency affect the power sector in Saudi Arabia? [journal article]. Energy Efficiency, 9(3), 771–790. doi:10.1007/s12053-015-9392-9.
Meltzer, J., Hultman, N., & Langley, C. (2014). Low-carbon energy transitions in Qatar and the GCC region. Brookings Institution.
MEP (2010). Ninth Development Plan (2010–2014). (Vol. ISSN: 1319–4836). Available: http://www.mep.gov.sa/ access: [Dec 2015]: Ministry of Economy and Planning
MMRA (2016). Statistics of construction licenses. Accessed 07/01/2016.
MoF (2016). Ministry’s of Finance statement about the national budget for 2016. In B. Information (Ed.), (pp. 1–17).
MOWE. (2009). Electricity growth and development in the Kingdom of Saudi Arabia. Riyadh: Annual Report, Ministry of Water and Electricity.
Nachet, S., & Aoun, M. C. (2015). The Saudi electricity sector: pressing issues and challenges. Note de l’Ifri, IFRI Research Center.
Obaid, R. R., & Mufti, A. H. 2008 Present state, challenges, and future of power generation in Saudi Arabia. In Energy 2030 Conference, 2008. ENERGY 2008. IEEE, 17–18 Nov. 2008 (pp. 1–6). doi:10.1109/ENERGY.2008.4781073.
Rehman, H. (2012). Saudi petrochemicals: the end of the magic porridge pot? London: Citigroup.
Roodman, D. M., & Lenssen, N. (2005). A building revolution: how ecology and health concerns are transforming construction. Worldwatch Paper, 124(Worldwatch Institute, Washington, DC).
Şahin, A. Z., & Aksakal, A. (1998). 6th Arab International Solar Energy Conference: bringing solar energy into the Daylight. Wind power energy potential at the northeastern region of Saudi Arabia. Renewable Energy, 14(1), 435–440. doi:10.1016/S0960-1481(98)00100-1.
Said, S. A., & Abdulrahman, M. (1989). Energy efficiency of a building in the eastern province of Saudi Arabia: parametric analysis with DOE 2.1A. ASHRAE Transactions, 95(1), 147–152.
Saidur, R., Masjuki, H. H., & Jamaluddin, M. Y. (2007). An application of energy and exergy analysis in residential sector of Malaysia. Energy Policy, 35(2), 1050–1063.
Salama, A. M., & Amir, A. O. (2005). Paradigmatic trends in Arab architectural education: impacts and challenges. Istambul: For UIA Congress.
SBC (2007). Saudi Building Code. Available: http://www.mattam.net/sbc/pdf/12.pdf Accessed Jan 2016.
SEEC (2013). Building energy sector Accessed 12/09/2015.
SEEC (2015a). Energy efficiency in KSA: annual report 2014. Saudi Energy Efficiency Center. Available: http://www.seec.gov.sa [Accessed: 06-Jan-2016].
SEEC (2015b). Energy efficiency in KSA: Saudi Energy Efficiency Center, Annual Report 2014. Available: http://www.seec.gov.sa Accessed 06 Jan 2016.
SGBC (2016). Saudi Green Building Council Website.
Sidawi, B. (2009). Hindrances to the financing of affordable housing in the Kingdom of Saudi Arabia Emirates. Journal for Engineering Research, 14(1), 73–82.
Stephen, J., & Michael, H. (2013). Developments in renewable energy in Saudi Arabia. White paper.
SUNPOWER (2016). Case study | KAUST. Available: https://global.sunpower.com/solar-case-studies/kaust-saudi-arabia Accessed 15 Sep 2016.
Taleb, H. M., & Sharples, S. (2011). Developing sustainable residential buildings in Saudi Arabia: a case study. Applied Energy, 88(1), 383–391. doi:10.1016/j.apenergy.2010.07.029.
Tham, K. W. (1993). Conserving energy without sacrificing thermal comfort. Building and Environment, 28(3), 287–299. doi:10.1016/0360-1323(93)90034-Z.
Tlili, I. (2015). Renewable energy in Saudi Arabia: current status and future potentials. [journal article]. Environment, Development and Sustainability, 17(4), 859–886. doi:10.1007/s10668-014-9579-9.
UN, U. N. (2012). United Nations common country strategic framework: Kingdom of Saudi Arabia 2012–2016. Available: http://www4.unfccc.int/nap/Country%20Documents/Parties/Saudia-Arabia---CCSF.pdf Accessed 06 Jan 2016.
UNDP, U. N. D. P. (2013). Sustainable development policy & planning: Saudi Arabia. Available: http://www.undp.org/content/dam/saudi_arabia/docs/Projects/79795pd.pdf Accessed: 18 Dec 2015.
UNEP, S. (2009). Buildings and climate change: a summary for decision-makers. Paris: United Nation Environmental Programme, Sustainable Buildings and Climate Initiative.
Weatherbase. (2011). Weatherbase: weather for Riyadh, Saudi Arabia. Retrieved on November 23, 2011.
Yilmaz, Z. (2007). Evaluation of energy efficient design strategies for different climatic zones: comparison of thermal performance of buildings in temperate-humid and hot-dry climate. Energy and Buildings, 39(3), 306–316.
Zuhairy, A. A., & Sayigh, A. A. M. (1995). Simulation and modeling of solar radiation in Saudi Arabia. Renewable Energy, 6(2), 107–118. doi:10.1016/0960-1481(94)00056-C.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Al-Tamimi, N. A state-of-the-art review of the sustainability and energy efficiency of buildings in Saudi Arabia. Energy Efficiency 10, 1129–1141 (2017). https://doi.org/10.1007/s12053-017-9507-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12053-017-9507-6