Deployable Membrane-Based Energy Technologies: the Ethiopian Prospect

Membrane-based energy technologies are presently gaining huge interest due to the fundamental engineering and potentially broad range of applications, with economic advantages over some of the competing technologies. Herein, we assess the potential deployability of the existing and emerging membrane...

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Veröffentlicht in:	Sustainability 2020-11, Vol.12 (21), p.8792
Hauptverfasser:	Besha, Abreham Tesfaye, Tsehaye, Misgina Tilahun, Tiruye, Girum Ayalneh, Gebreyohannes, Abaynesh Yihdego, Awoke, Aymere, Tufa, Ramato Ashu
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Schlagworte:	Alternative energy sources Biomass energy Carbon dioxide Clean energy Clean technology Developing countries Economic growth Electric power Electricity Electricity distribution Electrodialysis Electrolytic cells Emitters Energy Energy consumption Energy industry Energy policy Energy resources Energy technology Environmental policy Fossil fuels Fuel technology Hydroelectric power Hydrogen production Industrial plant emissions LDCs Membranes Osmosis Power plants Renewable resources Seawater Solar energy Solar power Sustainability Sustainable development Technology planning
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container_title	Sustainability
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creator	Besha, Abreham Tesfaye Tsehaye, Misgina Tilahun Tiruye, Girum Ayalneh Gebreyohannes, Abaynesh Yihdego Awoke, Aymere Tufa, Ramato Ashu
description	Membrane-based energy technologies are presently gaining huge interest due to the fundamental engineering and potentially broad range of applications, with economic advantages over some of the competing technologies. Herein, we assess the potential deployability of the existing and emerging membrane-based energy technologies (MEnT) in Ethiopia. First, the status of the current energy technologies is provided along with the active energy and environmental policies to shape the necessary research strategies for technology planning and implementation. Ethiopia is a landlocked country, which limits the effective extraction of energy, for instance, from seawater using alternative, clean technologies such as reverse electrodialysis and pressure retarded osmosis. However, there exists an excess off-grid solar power (up to 5 MW) and wind which can be used to drive water electrolyzers for hydrogen production. Hydrogen is a versatile energy carrier that, for instance, can be used in fuel cells providing zero-emission solutions for transport and mobility. Although Ethiopia is not among the largest CO2 emitters, with more than 90% energy supply obtained from waste and biomass, the economic and industrial growth still calls for alternative CO2 capture and use technologies, which are highlighted in this work. We believe that the present work provides (i) the status and potential for the implementation of MEnT in Ethiopia (ii) and basic guidance for researchers exploring new energy pathways toward sustainable development in developing countries.
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Although Ethiopia is not among the largest CO2 emitters, with more than 90% energy supply obtained from waste and biomass, the economic and industrial growth still calls for alternative CO2 capture and use technologies, which are highlighted in this work. 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subjects	Alternative energy sources Biomass energy Carbon dioxide Clean energy Clean technology Developing countries Economic growth Electric power Electricity Electricity distribution Electrodialysis Electrolytic cells Emitters Energy Energy consumption Energy industry Energy policy Energy resources Energy technology Environmental policy Fossil fuels Fuel technology Hydroelectric power Hydrogen production Industrial plant emissions LDCs Membranes Osmosis Power plants Renewable resources Seawater Solar energy Solar power Sustainability Sustainable development Technology planning
title	Deployable Membrane-Based Energy Technologies: the Ethiopian Prospect
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