{"id":19934,"date":"2022-03-30T13:21:36","date_gmt":"2022-03-30T12:21:36","guid":{"rendered":"https:\/\/www.innovationnewsnetwork.com\/?post_type=ebook&p=19934"},"modified":"2022-03-30T13:21:36","modified_gmt":"2022-03-30T12:21:36","slug":"improving-lithium-ion-battery-safety-for-electric-vehicles","status":"publish","type":"ebook","link":"https:\/\/www.innovationnewsnetwork.com\/ebook\/improving-lithium-ion-battery-safety-for-electric-vehicles\/","title":{"rendered":"Improving lithium-ion battery safety for electric vehicles"},"content":{"rendered":"

In this latest eBook from the Karlsruhe Institute of Technology (KIT)<\/a>, Dr Carlos Ziebert, Head of the Calorimeter Center, discusses the importance of improving lithium-ion battery safety for electric vehicles, and the significant role that calorimetry plays in this.<\/h2>\n

With the announcement of the Sustainable and Smart Mobility Strategy<\/a> that was communicated by the European Commission, the EU\u2019s transport sector intends to substantially reduce its emissions. Alongside this strategy, over 30 million zero-emission vehicles are set to be operational on European roads by 2030.<\/p>\n

Due to this clean-energy transition, the lithium-ion battery, which is essential for the production of electric vehicles (EV), is seeing enormous increases in demand. The global demand for lithium battery materials has doubled since 2020, originating at 300,000 tonnes of lithium carbonate equivalent in 2020, to 650,000 tones of lithium carbonate equivalent in 2022. Due to this rapid increase, the need to improve the energy density and lithium-ion battery safety for electric vehicles is being encouraged.<\/p>\n

This eBook also discusses:<\/p>\n