Advanced European lithium sulphur cells for automotive applications (EUROLIS)
Forskningsprojekt, 2012 – 2016

Li-ion batteries become a reality in the future vehicles, although they do not fulfil completely the demands of consumers. In this respect batteries with higher energy density are required. Lithium technology utilizing sulphur as a cathode is one of the optimal choices since it offers the possibility of achieving high-energy, long-life storage batteries with a potential low price. At present, the practical use is faced with two major problems: (i) a low intrinsic conductivity of sulphur and polysulphides and (ii) loss of active materials due to solubility of the intermediate products in the commonly used electrolytes. The low intrinsic conductivity can be overcome using improved electronic wiring. The occurrence of soluble polysulphides is reflected as a loss of the active material during the cycling and additionally soluble polysulphides are responsible for overcharging problem which lowers the energy efficiency. With an aim to have stable capacity retention with a good cycling efficiency it is important to find a suitable electrochemical environment for the lithium sulphur batteries. Possible approaches are using polysulphide reservoirs with modified surfaces in the highly mesoporous conductive matrix. Proposed system with high surface area should enable weak adsorption of polysulphides intermediates allowing reversible desorption. This way a full utilization of the active material without significant losses can be obtained. In order to understand the influence of surface area and surface modification, including interactions between electrolyte and sulphur based cathode composite we need to have a reliable characterization techniques. In this respect different electrochemical, spectroscopic and physical characterization (in-situ or ex-situ) techniques can provide us valuable informations about the possible mechanism which can be used in planning of substrates for sulphur in the Li-S batteries.

Deltagare

Patrik Johansson (kontakt)

Kondenserade materiens fysik

Johan Scheers

Kondenserade materiens fysik

Samarbetspartners

Center odličnosti nizkoogljične tehnologije (CO NOT)

Ljubljana, Slovenia

Centre national de la recherche scientifique (CNRS)

Paris, France

Elettra Sincrotrone Trieste

Basovizza Trieste, Italy

Fraunhofer-Gesellschaft

Munchen, Germany

Kemijski Inštitut

Ljubljana, Slovenia

Max-Planck-Gesellschaft

München, Germany

Renault

Boulogne Billancourt, France

Saft

Bagnolet, France

Solvionic

Toulouse, France

Volvo Group

Gothenburg, Sweden

Finansiering

Europeiska kommissionen (EU)

Projekt-id: EC/FP7/314515
Finansierar Chalmers deltagande under 2012–2016

Mer information

Projektets webbplats

http://www.eurolis.eu

Senast uppdaterat

2022-04-06