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Much of the rural poor-who are growing in number-are concentrated in ecologically fragile and remote areas. The key ecological scarcity problem facing such poor households is a vicious cycle of declining livelihoods, increased ecological degradation and loss of resource commons, and declining ecosystem services on which the poor depend. In addition, developing economies with high concentrations of their populations on fragile lands and in remote areas not only display high rates of rural poverty, but also are some of the poorest countries in the world today. Policies to eradicate poverty therefore need to be targeted at the poor where they live, especially the rural poor clustered in fragile environments and remote areas. The specific elements of such a strategy include involving the poor in payment for ecosystem services schemes and other measures that enhance the environments on which the poor depend; targeting investments directly to improving the livelihoods of the rural poor, thus reducing their dependence on exploiting environmental resources; tackling the lack of access of the rural poor in less favored areas to well-functioning and affordable markets for credit, insurance, and land; and reducing the high transportation and transaction costs that prohibit the poorest households in remote areas from engaging in off-farm employment and limit smallholder participation in national and global markets.

Banks & Banking Reform --- Developing countries --- Ecological scarcity --- Energy --- Environment --- Environmental Economics & Policies --- Green growth --- Macroeconomics and Economic Growth --- Natural capital --- Poverty-environment trap --- Regional Economic Development --- Rural poverty --- Rural Poverty Reduction --- Spatial poverty trap

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This Special Issue on “LCA of Energy Systems” contains inspiring contributions on assessing the sustainability of novel technologies destined to shape the future of our energy sector. These include battery-based and plug-in hybrid electric vehicles, geothermal energy, hydropower, biomass gasification, national electricity systems, and waste incineration. The analysis of trends and singularities will be invaluable to product designers, engineers, and policy makers. Furthermore, these exercises also contribute to refining the life cycle framework and harmonizing methodological decisions. Our hope is that this should be a step toward promoting the use of science and knowledge to shape a better world for everyone.

Research & information: general --- life cycle assessment --- battery electric vehicle (BEV) --- plug-in electric vehicle --- energy --- greenhouse gas (GHG) emissions --- thermodynamic modeling --- exergy --- e-waste --- secondary copper smelting --- precious metal recovery --- printed circuit board --- coalbed methane development --- risk assessment --- structural entropy weight method --- matter-element extension method --- LCA --- Spain --- renewables --- electricity --- sustainability --- carbon footprint --- employment --- LCOE --- CHP --- biomass --- gasification --- SOFC --- allocation --- multifunctionality --- geothermal energy --- flash technology --- Bagnore power plant --- pedigree matrix --- carbon dioxide capture --- activated carbon --- environmental impacts --- IGCC --- carbon capture economy --- stirling cycle-based heat pump --- gas/oil-fired boilers --- SimaPro --- eco-indicator 99 --- life cycle impact assessment --- distance-to-target weighting --- ecological scarcity --- renewable electricity and heat generation --- decentralized energy system

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

This Special Issue on “LCA of Energy Systems” contains inspiring contributions on assessing the sustainability of novel technologies destined to shape the future of our energy sector. These include battery-based and plug-in hybrid electric vehicles, geothermal energy, hydropower, biomass gasification, national electricity systems, and waste incineration. The analysis of trends and singularities will be invaluable to product designers, engineers, and policy makers. Furthermore, these exercises also contribute to refining the life cycle framework and harmonizing methodological decisions. Our hope is that this should be a step toward promoting the use of science and knowledge to shape a better world for everyone.

Research & information: general --- life cycle assessment --- battery electric vehicle (BEV) --- plug-in electric vehicle --- energy --- greenhouse gas (GHG) emissions --- thermodynamic modeling --- exergy --- e-waste --- secondary copper smelting --- precious metal recovery --- printed circuit board --- coalbed methane development --- risk assessment --- structural entropy weight method --- matter-element extension method --- LCA --- Spain --- renewables --- electricity --- sustainability --- carbon footprint --- employment --- LCOE --- CHP --- biomass --- gasification --- SOFC --- allocation --- multifunctionality --- geothermal energy --- flash technology --- Bagnore power plant --- pedigree matrix --- carbon dioxide capture --- activated carbon --- environmental impacts --- IGCC --- carbon capture economy --- stirling cycle-based heat pump --- gas/oil-fired boilers --- SimaPro --- eco-indicator 99 --- life cycle impact assessment --- distance-to-target weighting --- ecological scarcity --- renewable electricity and heat generation --- decentralized energy system