2018
DOI: 10.1016/j.energy.2018.06.149
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Global material requirements for the energy transition. An exergy flow analysis of decarbonisation pathways

Abstract: Moving towards a low-carbon economy will imply a considerable increase in the deployment of green technologies, which will in turn increase the demand of certain raw materials. In this paper, the material requirements for 2050 scenarios are assessed in terms of exergy to analyze the impact in natural resources in each scenario and identify which technologies are going to demand more resources.Renewable energy technologies are more mineral intensive than current energy sources.Using the International Energy Age… Show more

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Cited by 90 publications
(41 citation statements)
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“…Although recycling rates are low for most critical metals used in PV technologies 20,54 , two scenarios for secondary supply (recycling potential (RP)) are used in the analysis. The first assumes no recycling for metals used in the PV technologies (WOR scenario) and the second assumes recycling rate of 50% for all metals (WR scenario).…”
Section: Methodsmentioning
confidence: 99%
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“…Although recycling rates are low for most critical metals used in PV technologies 20,54 , two scenarios for secondary supply (recycling potential (RP)) are used in the analysis. The first assumes no recycling for metals used in the PV technologies (WOR scenario) and the second assumes recycling rate of 50% for all metals (WR scenario).…”
Section: Methodsmentioning
confidence: 99%
“…The most relevant materials, among those used in PV solar technologies, in terms of energy, water, and CO 2 emissions are Al, Fe, and concrete, not because their energy intensities are expected to increase (as a result of decreasing ore grade or lower energy efficiency) but mainly due to the quantities used in these technologies. Several values for Al, steel, and concrete intensities of PV solar have been reported 20,70,71 . Minimum, maximum, and average Al intensity in PV is assumed 19 Mg/MW, 33 Mg/MW, and 26 Mg/MW, steel intensity is assumed 178 Mg/MW, 318 Mg/MW, and 251 Mg/MW, and concrete intensity is assumed 672 Mg/MW, 2846 Mg/MW, and 1823 Mg/MW based on values reported in 71 for average literature data.…”
Section: Methodsmentioning
confidence: 99%
“…To retain the same units, we evaluated each metal demand in terms of its exergy replacement cost rather than in tonnage. However, tonnage was also assessed as explained in Valero et al [ 19 ].…”
Section: An Exergy Flow Analysis Of the Energy Transitionmentioning
confidence: 99%
“…Five elements experience at least a six-fold increase in demand in exergy replacement cost terms—cobalt, lithium, magnesium, titanium, and zinc. Further, the growth in phosphates and potassium demand both for fertilizers and bioenergy use is expected to double by 2050 [ 19 ]. Figure 1 shows that to approach a decarbonized economy by 2050, the replacement cost of the minerals used (9355 Mtoe) is greater than the energy provided by all fossil fuels and nuclear energy (6405 + 1789 Mtoe) and even by all renewable energies (6901 Mtoe).…”
Section: An Exergy Flow Analysis Of the Energy Transitionmentioning
confidence: 99%
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