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Use of renewable energies in rural areas in the island of Crete, Greece has been investigated. Crete has rich indigenous renewable energy resources which are currently utilized for covering part of its energy requirements. Various renewable energy technologies used for heat and electricity generation in the island have been examined. Solar energy, wind energy, hydro power, biomass, and low enthalpy geothermal energy are already used. The total installed electric power of renewable energies in Crete, located mostly in rural areas, is approximately at 30% of the total electric power installed. They currently generate more than 20% of the island’s annual electricity needs. More renewable energy applications are foreseen in the future in rural areas in Crete as soon as its electric grid will be interconnected with the country’s continental grid. New renewable energy technologies, which are not currently used, could generate in the future heat, cooling, electricity, and vehicle’s fuels in the island. Their use will have positive impacts including the promotion of energy investments, lower use of imported and polluting fossil fuels, de-carbonization of the island’s energy sector as well as creation of new local jobs. It is indicated that the rich renewable energy resources in Crete could provide almost all of its annual energy needs. This will result in Crete’s transformation to a low or zero carbon economy in accordance with EU targets for zero carbon emissions in the next decades complying with the global goal for climate change mitigation.

References

  1. R. Ciriminna, M. Pagliaro, F. Meneguzzo, & M. Peoraino, “Solar energy for Sicily’s remote islands: On the route from fossil to renewable energy”, International Journal of Sustainable built Environment, Vol. 5, pp. 132-140, 2016. http://dx.doi.org/10.1016/j.ijsbe.2016.04.003.
     Google Scholar
  2. V. Franzitta, D. Gurto, & D. Rao, “Energetic sustainability using renewable energies in the Mediterranean Sea”, Sustainability, 8, 1164, 2016. doi:10.3390/su8111164.
     Google Scholar
  3. I. Kougias, S. Szabo, A. Nikitas, & N. Theodosiou, “Sustainable energy modeling of non-interconnected Mediterranean islands”, Renewable Energy, Vol. 133, pp. 930-940, 2019. https://doi.org/10.1016/j.renene.2018.10.090.
     Google Scholar
  4. EU islands in the energy transition. A catalogue of good practices, Clean Energy for EU Islands, 2019. Available: https://euislands.eu/eu-islands-good-practices.
     Google Scholar
  5. I. Efthymiopoulos, “Islands as test beds for innovative energy solutions”, Seminar held in Athens, Greece, November 9-10, 2015.
     Google Scholar
  6. Tsekeris, D. (2019). The energy transition of the Greek non-interconnected islands, Greek Ministry of Environment and Energy. Available: https://hybridpowersystems.org/crete2019/downloads/.
     Google Scholar
  7. O. Christopoulou, M. Fountoukidou, St. Sakellariou, St. Tampekis, F. Samara, A. Sfoungaris, A. Stergiadou, G. Tsantopoulos, K. Soutsas, & I. Sfoungaris, “Energy Autonomy in Small Islands in the Frame of Their Sustainable Development Exploring Biomass Energy Potential in Samothrace (Greece)”, International Journal of Sustainable and Green Energy. Special Issue: Advances in Sustainability Assessment, Vol. 6(4-1), pp. 9-17, 2015. doi: 10.11648/j.ijrse.2015060401.12.
     Google Scholar
  8. Ch. Ioakimidis, & K.N. Genikomsakis “Integration of seawater pump-storage in the energy system of the island of Sao Miguel (Azores)”, Sustainability, Vol. 10, 3438, 2018. doi:10.3390/su10103438.
     Google Scholar
  9. H. Dorotic, B. Dorasic, V. Dobravec, T. Puksec, G. Krajacic, & N. Duic, “Integration of transport and energy sectors in island communities with 100% intermittent renewable energy sources”, Renewable and Sustainable Energy Reviews, Vol. 99, pp. 109-124, 2019. https://doi.org/10.1016/j.rser.2018.09.033.
     Google Scholar
  10. G. Mihalakakou, B. Psiloglou, M. Santamouris, & D. Nomidis, “Application of renewable energy sources in the Greek islands of the South Aegean Sea”, Renewable Energy, Vol. 26(1), pp. 1-19, 2002. https://doi.org/10.1016/S0960-1481(01)00111-2.
     Google Scholar
  11. Renewable energy on islands: a pathway to prosperity, Climate Action, 2015. Available: http://www.climateaction.org/climate-leader-papers/renewable_energy_on_islands_a_pathway_to_prosperity.
     Google Scholar
  12. Z. Gkouskos, & Th. Tsoutsos, (September 2011). Solar application in the island of Crete. Examples of the renewable and sustainable energy lab, Technical University of Crete, in International Conference BIOSOL, Crete, Greece.
     Google Scholar
  13. A. Gigantidou, (August, 2013). Renewable energy sources in Crete. IREP Symposium – Bulk Power System Dynamics and Control. IX (IREP), Rethymno, Crete, Greece. Available: http://papers.irep2013.ntua.gr/83.pdf.
     Google Scholar
  14. I. Kougias, K. Bodis, A. Jager-Waldau, M. Moner-Girona, F. Monforti-Ferrario, H. Ossenbrink, & S. Szabo, “The potential of water infrastructure to accommodate solar-PV systems in Mediterranean islands”, Solar Energy, Vol. 136, pp. 174-182, 2016. http://dx.doi.org/10.1016/j.solener.2016.07.003.
     Google Scholar
  15. D. Katsaprakakis, I. Antonakakis, I., Dakanali, & D. Christakis, (May 2019). Turning Crete into an energy independent island. 4th International Hybrid Power Systems workshop, Crete, Greece. Available: https://www.researchgate.net/publication/333701601_Turning_Crete_into_an_energy_independent_island.
     Google Scholar
  16. J. Vourdoubas, “Present and future use of biomass for energy generation in the island of Crete, Greece”, Journal of Energy and Power Sources, Vol. 2(4), pp. 158-163 2015.
     Google Scholar
  17. S. Alatzas, K. Moustakas, D. Malamis, & S. Vakalis, “Biomass potential for agricultural waste for energetic utilization in Greece”, Energies, Vol. 12, 1095, 2019. doi:10.3390/en12061095.
     Google Scholar
  18. T. Nikolaou, G.S. Stavrakakis, & K. Tsamoudalis, “Modeling and optimal dimensioning of a pumped hydro energy storage system for the exploitation of the rejected wind energy in the non-interconnected electrical power system of the Crete island, Greece”, Energies, Vol. 13, 2705, 2020. doi:10.3390/en13112705.
     Google Scholar
  19. Reinforcing investments in biogas technologies for small scale RES applications in islands, BIORES, Intelligent Energy Europe. Available: https://ec.europa.eu/energy/intelligent/projects/en/projects/biores.
     Google Scholar
  20. J. G. Fantidis, D. V. Bandekas, N. Vordos, & S. Karachalios. (January-February 2013). Wind energy potential in Greece using a small wind turbine, Recent Advances in Energy, Environment and Development, Cambridge, Available: https://www.researchgate.net/publication/257929879_Wind_Energy_Potential_in_Greece_Using_a_Small_Wind_Turbine.
     Google Scholar
  21. Annual report on the energy system in Crete, (2018), Hellenic Electricity Distribution Network Operator (DEDDIE), (in Greek).
     Google Scholar
  22. A. A. Argiriou, & S. Mirasgedis, “The solar thermal market in Greece – review and perspectives”, Renewable and Sustainable Energy Reviews, Vol. 7(5), pp. 397-418, 2003. https://doi.org/10.1016/S1364-0321(03)00064-9.
     Google Scholar
  23. M. Karagiorgas, A. Botzios, & Th. Tsoutsos, “Industrial solar thermal applications in Greece: Economic evaluation, quality requirements and case studies”, Renewable and Sustainable Energy Reviews, Vol. 5(2), pp. 157-173, 2001. https://doi.org/10.1016/S1364-0321(00)00012-5.
     Google Scholar
  24. N. Scarlat, J-F. Dallemand, & F. Fahl, “Biogas: Developments and perspectives in Europe”, Renewable Energy, Vol. 129, pp. 457-472, 2018. https://doi.org/10.1016/j.renene.2018.03.006.
     Google Scholar
  25. Raboni, M. & Urbini, G. (2014). Production and use of biogas in Europe: a survey of current status and perspectives, Ambiente & Agua – An interdisciplinary Journal of Applied Science, 9(2), 191-202. doi: 10.4136/ambi-agua.1324.
     Google Scholar
  26. V. Aggarwal, Ch. Swaroop Meena, Ash. Kumar, T. Alam, An. Kumar, Arij. Ghosh, & Arit. Ghosh, “Potential and future prospects of geothermal energy in space conditioning of buildings: India and worldwide review”, Sustainability, Vol. 12, 8428, 2020. doi:10.3390/su12208428.
     Google Scholar
  27. Off-grid renewable energy systems: Status and methodological issues, IRENE, 2015. Available: https://www.irena.org/publications/2015/Feb/Off-grid-renewable-energy-systems-Status-and-methodological-issues.
     Google Scholar
  28. J. W. Lund, T. L. & Boyd, (April 2015). Direct utilization of geothermal energy 2015, Worldwide View, Proceedings World Geothermal Congress Melbourne, Australia. Available: https://www.unionegeotermica.it/pdfiles/usi-diretti-energia-geotermica-nel-mondo.pdf.
     Google Scholar
  29. Biomass production, supply, uses and flows in the European Union (2018), JRC Science for Policy report. Available: https://ec.europa.eu/jrc/en/publication/eur-scientific-and-technical-research-reports/biomass-production-supply-uses-and-flows-european-union-first-results-integrated-assessment.
     Google Scholar