We present a prospective life cycle assessment model for lithium-ion battery cell production for 8 battery chemistries and 3 production regions during 2020–2050.
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GHG emissions per kWh of lithium-ion battery cell production could reduce by over 50% during 2020–2050, mainly due to expected low-carbon electricity transition.
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Cathode component is, with 46%−70% for NCM/NCA cells and 33%−46% for LFP cells, the biggest contributor to GHG emissions of lithium-ion battery cell production until 2050.
Abstract
Understanding the future environmental impacts of lithium-ion batteries is crucial for a sustainable transition to electric vehicles. Here, we build a prospective life cycle assessment (pLCA) model for lithium-ion battery cell production for 8 battery chemistries and 3 production regions (China, US, and EU). The pLCA model includes scenarios for future life cycle inventory data for energy and key materials used in battery cell production. We find that greenhouse gas (GHG) emissions per kWh of lithium-ion battery cell production could be reduced from 41 to 89 kg CO2-Eq in 2020 to 10–45 kg CO2-Eq in 2050, mainly due to the effect of a low-carbon electricity transition. The Cathode is the biggest contributor (33%-70%) of cell GHG emissions in the period between 2020 and 2050. In 2050, LiOH will be the main contributor to GHG emissions of LFP cathodes, and Ni2SO4 for NCM/NCA cathodes. These results promote discussion on how to reduce battery GHG emissions.