Battery 2030+ Roadmap

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Fältnamn	Indikatorer	Metadata
000		06916nam a2200985 4500
001		oai:DiVA.org:uu-415669
003		SwePub
008		200703s2020 \| \|\|\|\|\|\|\|\|\|\|\|000 \|\|eng\|
024	7	a https://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-4156692 URI
024	7	a https://doi.org/10.33063/diva2-14520232 DOI
040		a (SwePub)uu
041		a engb eng
042		9 SwePub
072	7	a vet2 swepub-contenttype
072	7	a rap2 swepub-publicationtype
100	1	a Edström, Kristina,c Professor,d 1958-u Uppsala universitet,Strukturkemi,Battery 2030+4 aut0 (Swepub:uu)ked02526
245	1 0	a Battery 2030+ Roadmap
264		c 2020
264	1	b Uppsala University,c 2020
300		a 84 s.
338		a electronic2 rdacarrier
520		a Climate change is the biggest challenge facing the world today. Europe is committed to achieving a climate-neutral society by 2050, as stated in the European Green Deal.1 The transition towards a climate-neutral Europe requires fundamental changes in the way we generate and use energy. If batteries can be made simultaneously more sustainable, safe, ultrahigh performing, and affordable, they will be true enablers, “accelerating the shift towards sustainable and smart mobility; supplying clean, affordable and secure energy; and mobilizing industry for a clean and circular economy” - all of which are important elements of the UN Sustainable Development Goals.In other words, batteries are a key technology for battling carbon dioxide emissions from the transport, power, and industry sectors. However, to reach our sustainability goals, batteries must exhibit ultra-high performance beyond their capabilities today. Ultra-high performance includes energy and power performance approaching theoretical limits, outstanding lifetime and reliability, and enhanced safety and environmental sustainability. Furthermore, to be commercially successful, these batteries must support scalability that enables cost-effective large-scale production.BATTERY 2030+, is the large-scale, long-term European research initiative with the vision of inventing the sustainable batteries of the future, to enable Europe to reach the goals envisaged in the European Green Deal. BATTERY 2030+ is at the heart of a green and connected society.BATTERY 2030+ will contribute to create a vibrant battery research and development (R&D) community in Europe, focusing on long-term research that will continuously feed new knowledge and technologies throughout the value chain, resulting in new products and innovations. In addition, the initiative will attract talent from across Europe and contribute to ensure access to competences needed for ongoing societal transformation.The BATTERY 2030+ aims are:• to invent ultra-high performance batteries that are safe, affordable, and sustainable, witha long lifetime.• to provide new tools and breakthrough technologies to the European battery industrythroughout the value chain.• to enable long-term European leadership in both existing markets (e.g., transport andstationary storage) and future emerging sectors (e.g., robotics, aerospace, medical devices, and Internet of things)With this roadmap, BATTERY 2030+ advocates research directions based on a chemistry-neutral approach that will allow Europe to reach or even surpass its ambitious battery performance targets set in the European Strategic Energy Technology Plan (SET-Plan)3 and foster innovation throughout the battery value chain.
650	7	a NATURVETENSKAPx Kemix Materialkemi0 (SwePub)104032 hsv//swe
650	7	a NATURAL SCIENCESx Chemical Sciencesx Materials Chemistry0 (SwePub)104032 hsv//eng
653		a Materials Acceleration Platform (MAP)
653		a Battery Interface Genome (BIG)
653		a Climate-neutral chemistry
653		a Batteries
653		a EU project
653		a Self-healing batteries
653		a Recyclability
653		a Kemi med inriktning mot materialkemi
653		a Chemistry with specialization in Materials Chemistry
700	1	a Dominko, Robertu Battery 2030+
700	1	a Fichtner, Maximilianu Battery 2030+
700	1	a Perraud, Simonu Battery 2030+
700	1	a Punckt, Christianu Battery 2030+
700	1	a Asinari, Pieitrou Battery 2030+
700	1	a Eligio Castelli, Ivanou Battery 2030+
700	1	a Christensen, Runeu Battery 2030+
700	1	a Clark, Simonu Battery 2030+
700	1	a Grimaud, Alexisu Battery 2030+
700	1	a Hermansson, Kersti,c Professoru Uppsala universitet,Strukturkemi,Battery 2030+0 (Swepub:uu)kerstihs
700	1	a Heuer, Andreasu Battery 2030+
700	1	a Lorrmann, Henningu Battery 2030+
700	1	a Lovvik, Ole Martinu Battery 2030+
700	1	a Vegge, Tejsu Battery 2030+
700	1	a Wenzel, Wolfgangu Battery 2030+
700	1	a Bayle-Guillemaud, Pascalu Battery 2030+
700	1	a Behm, Jürgenu Battery 2030+
700	1	a Berg, Eriku Uppsala universitet,Strukturkemi,Battery 2030+0 (Swepub:uu)erija234
700	1	a Hahlin, Mariau Uppsala universitet,Molekyl- och kondenserade materiens fysik,Strukturkemi,Battery 2030+0 (Swepub:uu)mahed424
700	1	a Hartmann, Sarau Battery 2030+
700	1	a Latz, Arnulfu Battery 2030+
700	1	a Lyonnard, Sandrineu Battery 2030+
700	1	a Amici, Juliau Battery 2030+
700	1	a Berecibar, Maitaneu Battery 2030+
700	1	a Bodoardo, Silviau Battery 2030+
700	1	a Jabbour, Larau Battery 2030+
700	1	a Kallo, Josefu Battery 2030+
700	1	a Paillard, Elie-Elysséu Battery 2030+
700	1	a Raccurt, Olivieru Battery 2030+
700	1	a Heiries, Vincentu Battery 2030+
700	1	a Guillet, Nicolasu Battery 2030+
700	1	a Tarascon, Jean-Marieu Battery 2030+
700	1	a Van Laethem, Driesu Battery 2030+
700	1	a Ayerbe, Elixabeteu Battery 2030+
700	1	a Diehm, Ralfu Battery 2030+
700	1	a Hofmann, Jannau Battery 2030+
700	1	a Miguel, Oscaru Battery 2030+
700	1	a Meeus, Marcelu Battery 2030+
700	1	a Placke, Tobiasu Battery 2030+
700	1	a Sheridan, Edelu Battery 2030+
700	1	a Barboux, Philippeu Battery 2030+
700	1	a Chanson, Clauseu Battery 2030+
700	1	a Jacques, Philippeu Battery 2030+
700	1	a Trapp, Victoru Battery 2030+
700	1	a Weil, Marcelu Battery 2030+
710	2	a Uppsala universitetb Strukturkemi4 org
856	4	u https://doi.org/10.33063/diva2-1452023y Fulltext
856	4	u https://uu.diva-portal.org/smash/get/diva2:1452023/FULLTEXT01.pdfx primaryx Raw objecty fulltext
856	4	u https://uu.diva-portal.org/smash/get/diva2:1452023/PREVIEW01.pngx Previewy preview image
856	4	u http://uu.diva-portal.org/smash/get/diva2:1452023/FULLTEXT01
856	4 8	u https://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-415669
856	4 8	u https://doi.org/10.33063/diva2-1452023

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Av författaren/redakt...: Edström, Kristin ...; Dominko, Robert; Fichtner, Maximi ...; Perraud, Simon; Punckt, Christia ...; Asinari, Pieitro; visa fler...; Eligio Castelli, ...; Christensen, Run ...; Clark, Simon; Grimaud, Alexis; Hermansson, Kers ...; Heuer, Andreas; Lorrmann, Hennin ...; Lovvik, Ole Mart ...; Vegge, Tejs; Wenzel, Wolfgang; Bayle-Guillemaud ...; Behm, Jürgen; Berg, Erik; Hahlin, Maria; Hartmann, Sara; Latz, Arnulf; Lyonnard, Sandri ...; Amici, Julia; Berecibar, Maita ...; Bodoardo, Silvia; Jabbour, Lara; Kallo, Josef; Paillard, Elie-E ...; Raccurt, Olivier; Heiries, Vincent; Guillet, Nicolas; Tarascon, Jean-M ...; Van Laethem, Dri ...; Ayerbe, Elixabet ...; Diehm, Ralf; Hofmann, Janna; Miguel, Oscar; Meeus, Marcel; Placke, Tobias; Sheridan, Edel; Barboux, Philipp ...; Chanson, Clause; Jacques, Philipp ...; Trapp, Victor; Weil, Marcel; visa färre...

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