SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4313479854> ?p ?o ?g. }

Showing items 1 to 100 of ±142 with 100 items per page.

W4313479854 endingPage "126596" @default.
W4313479854 startingPage "126596" @default.
W4313479854 abstract "Limiting global warming well below 2 °C requires substantial increase in the installation of low-carbon electricity generation technologies (EGTs). EGTs however require several critical materials and materials associated with considerable energy, water and CO2 emissions. This paper assesses the implications of materials and energy efficiencies for climate change mitigation potential of global energy transition scenarios (GETS). The analysis is carried out using a dynamic material flow-stock model for 21 materials and 15 scenarios combining GETS developed by international organizations including International Energy Agency (IEA) and Greenpeace (GP), materials scenarios, and energy, water, and emissions intensities scenarios. Materials related CO2 emissions are expected to constitute between 4% and 14% the emissions reported in the IEA Sustainable Development scenario, while expected to be between 10% and 28% in GP Advanced Revolution scenario. Increasing material efficiency and reducing emissions intensities (driven by increasing energy efficiency, renewable technologies in energy supply mix, and recycling) reduce cumulative emissions by 73.2% and 26.3% respectively, while both reduce emissions by 79.5%. Increasing materials efficiency in EGT, energy and water efficiency in mining activities mainly for iron, aluminium, and nickel, and recycling, combined with careful selection of EGTs are significant to realize the full potential of GETS in climate change mitigation." @default.
W4313479854 created "2023-01-06" @default.
W4313479854 creator A5047108940 @default.
W4313479854 date "2023-03-01" @default.
W4313479854 modified "2023-10-02" @default.
W4313479854 title "The implications of material and energy efficiencies for the climate change mitigation potential of global energy transition scenarios" @default.
W4313479854 cites W1485611434 @default.
W4313479854 cites W1500960092 @default.
W4313479854 cites W1522423633 @default.
W4313479854 cites W1571574068 @default.
W4313479854 cites W1800856591 @default.
W4313479854 cites W1950418469 @default.
W4313479854 cites W1979912617 @default.
W4313479854 cites W1999595821 @default.
W4313479854 cites W2004273741 @default.
W4313479854 cites W2028088809 @default.
W4313479854 cites W2036919673 @default.
W4313479854 cites W2036960025 @default.
W4313479854 cites W2046102090 @default.
W4313479854 cites W2055307036 @default.
W4313479854 cites W2061982636 @default.
W4313479854 cites W2066446906 @default.
W4313479854 cites W2074251079 @default.
W4313479854 cites W2079288045 @default.
W4313479854 cites W2094190622 @default.
W4313479854 cites W2099859520 @default.
W4313479854 cites W2111061615 @default.
W4313479854 cites W2113231897 @default.
W4313479854 cites W2137261917 @default.
W4313479854 cites W2320131709 @default.
W4313479854 cites W2345340035 @default.
W4313479854 cites W2411407008 @default.
W4313479854 cites W2461718668 @default.
W4313479854 cites W2468724533 @default.
W4313479854 cites W2509566783 @default.
W4313479854 cites W2518230131 @default.
W4313479854 cites W2527147387 @default.
W4313479854 cites W2534620331 @default.
W4313479854 cites W2592402572 @default.
W4313479854 cites W2608463171 @default.
W4313479854 cites W2735279574 @default.
W4313479854 cites W2756231227 @default.
W4313479854 cites W2794078178 @default.
W4313479854 cites W2799398061 @default.
W4313479854 cites W2805147302 @default.
W4313479854 cites W282930240 @default.
W4313479854 cites W2895351408 @default.
W4313479854 cites W2896590868 @default.
W4313479854 cites W2908881146 @default.
W4313479854 cites W2909102426 @default.
W4313479854 cites W2922128407 @default.
W4313479854 cites W2944839667 @default.
W4313479854 cites W2946482034 @default.
W4313479854 cites W2946490814 @default.
W4313479854 cites W2949410986 @default.
W4313479854 cites W2968855319 @default.
W4313479854 cites W2980257798 @default.
W4313479854 cites W2990509501 @default.
W4313479854 cites W2991117080 @default.
W4313479854 cites W3010515282 @default.
W4313479854 cites W3022343789 @default.
W4313479854 cites W3088259427 @default.
W4313479854 cites W3154945937 @default.
W4313479854 cites W3195630781 @default.
W4313479854 cites W3198878814 @default.
W4313479854 doi "https://doi.org/10.1016/j.energy.2022.126596" @default.
W4313479854 hasPublicationYear "2023" @default.
W4313479854 type Work @default.
W4313479854 citedByCount "5" @default.
W4313479854 countsByYear W43134798542023 @default.
W4313479854 crossrefType "journal-article" @default.
W4313479854 hasAuthorship W4313479854A5047108940 @default.
W4313479854 hasConcept C115343472 @default.
W4313479854 hasConcept C119599485 @default.
W4313479854 hasConcept C121332964 @default.
W4313479854 hasConcept C127413603 @default.
W4313479854 hasConcept C132651083 @default.
W4313479854 hasConcept C134560507 @default.
W4313479854 hasConcept C142724271 @default.
W4313479854 hasConcept C162324750 @default.
W4313479854 hasConcept C163258240 @default.
W4313479854 hasConcept C175605778 @default.
W4313479854 hasConcept C188573790 @default.
W4313479854 hasConcept C18903297 @default.
W4313479854 hasConcept C204787440 @default.
W4313479854 hasConcept C206658404 @default.
W4313479854 hasConcept C26993612 @default.
W4313479854 hasConcept C2742236 @default.
W4313479854 hasConcept C2777890234 @default.
W4313479854 hasConcept C39432304 @default.
W4313479854 hasConcept C423512 @default.
W4313479854 hasConcept C47737302 @default.
W4313479854 hasConcept C509746633 @default.
W4313479854 hasConcept C62520636 @default.
W4313479854 hasConcept C71924100 @default.
W4313479854 hasConcept C86803240 @default.
W4313479854 hasConcept C87717796 @default.
W4313479854 hasConceptScore W4313479854C115343472 @default.