Nonregenerative Natural Resources in a Sustainable System of Energy Supply

Nonregenerative Natural Resources in a Sustainable System of Energy Supply

Following the lead of the European Union in introducing binding measures to promote the use of regenerative energy forms, it is not unreasonable to assume that the global demand for combustible raw materials for energy generation will be reduced considerably in the second half of this century. This...

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Veröffentlicht in:ChemSusChem 2012-03, Vol.5 (3), p.550-562
Hauptverfasser: Bradshaw, Alex M., Hamacher, Thomas
Format: Artikel
Sprache:eng
Schlagworte:
Carbon dioxide
Carbon dioxide concentration
Chemical industry
Conservation of Natural Resources
copper
Demand
Depletion
Electric power distribution
European Union
Exhaustion
Fossil fuels
Lithium
Metals - chemistry
Mineral resources
Natural resources
Permanent magnets
Photovoltaic cells
rare earths
Raw materials
Renewable Energy
Solar cells
sustainable chemistry
Tellurium
Wind turbines
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Hamacher, Thomas
description Following the lead of the European Union in introducing binding measures to promote the use of regenerative energy forms, it is not unreasonable to assume that the global demand for combustible raw materials for energy generation will be reduced considerably in the second half of this century. This will not only have a favourable effect on the CO2 concentration in the atmosphere, but will also help preserve fossil fuels—important as raw materials in the chemical industry—for future generations. Nevertheless, associated with the concomitant massive shift to regenerative energy forms, there will be a strong demand for other exhaustible raw materials, in particular metals, some of which are already regarded as scarce. After reviewing the debate on mineral depletion between “cornucopians” and “pessimists”, we discuss the meaning of mineral “scarcity”, particularly in the geochemical sense, and mineral “exhaustion”. The expected drastic increase in demand for mineral resources caused by demographic and societal pressures, that is, due to the increase in in‐use stock, is emphasised. Whilst not discussing the issue of “strong” versus “weak” sustainability in detail, we conclude that regenerative energy systems—like nearly all resource‐consuming systems in our society—do not necessarily satisfy generally accepted sustainability criteria. In this regard, we discuss some current examples, namely, lithium and cobalt for batteries, rare earth‐based permanent magnets for wind turbines, cadmium and tellurium for solar cells and copper for electrical power distribution. Rare and precious: Following the lead taken by the EU in energy and climate policy, a shift from fossil fuels to regenerative energy will have occurred globally by the second half of this century. This will be accompanied by a strong demand for other exhaustible raw materials, in particular metals. The terms “sustainability”, “depletion” and “scarcity” are examined in the context of mineral supply and the situation with regard to some rare metals is discussed.
doi_str_mv 10.1002/cssc.201100563
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subjects Carbon dioxide
Carbon dioxide concentration
Chemical industry
Conservation of Natural Resources
copper
Demand
Depletion
Electric power distribution
European Union
Exhaustion
Fossil fuels
Lithium
Metals - chemistry
Mineral resources
Natural resources
Permanent magnets
Photovoltaic cells
rare earths
Raw materials
Renewable Energy
Solar cells
sustainable chemistry
Tellurium
Wind turbines
title Nonregenerative Natural Resources in a Sustainable System of Energy Supply
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