Electric vehicle battery state changes and reverse logistics considerations

Abstract

ABSTRACT Electric Vehicles are becoming trendy and proved to have no harmful exhaust like traditional fuel-powered vehicles. As the world shifts towards electric vehicle adoption, lithium-ion batteries are becoming the primary power source for this transition. The goal of this research is to analyze the lifespan and long-term ratio composition of Lithium-Ion batteries in electric vehicles by developing two models, an Absorbing Markov Chain model, and a Markov Chain Steady-State Census model. A sensitivity analysis is also conducted to alleviate the scarcity of enough input data. This research work shows that the lifespan of batteries can be extended by 4.5 years, which will have a positive environmental impact and reap economic benefits. Moreover, the long-term composition of batteries in New, Remanufactured, Repurposed and Recycled states can be projected. By considering reverse logistics processes, it is possible to recycle batteries and recover the valuable materials otherwise lost. Not only does this support the environment but given the rising demand and finite raw material supply, there is an opportunity to capture the economic benefit of recycling. From this research, the recovered materials cobalt, lithium, and nickel are calculated, and this is especially important for the optimal planning of sustainable manufacturing