Regional prioritization in vehicle electrification and renewable electricity expansion facilitates decarbonization of China’s road transport

Xiang Li; Xiaoyu Yan

doi:10.20517/cf.2025.47

Carbon Footprints ›› 2025, Vol. 4 ›› Issue (4) :32 DOI: 10.20517/cf.2025.47

Original Article

Regional prioritization in vehicle electrification and renewable electricity expansion facilitates decarbonization of China’s road transport

Xiang Li ¹^,²
, Xiaoyu Yan ¹^,²

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Abstract

Previous studies indicate that rapid electric vehicle (EV) adoption, together with synchronized expansion of renewable electricity (RE) in all power grid regions, could significantly reduce life cycle carbon emissions from China’s road transport sector. However, the varying pace of EV and RE development in different regions complicates this goal. There is a lack of research analyzing the impact of prioritizing vehicle electrification and RE expansion within specific power grid regions on national life cycle carbon emission reductions. This study employed a highly disaggregated engineering-based model to estimate the life cycle carbon emissions from China’s road transport from the base year 2020 up to 2050 under various EV and RE development scenarios with different regional priorities. The underlying reasons and key processes driving variations in carbon emission reductions at the power grid region level were also analyzed. Our results indicate that the Central and Northwest power grid regions contributed the most and least to life cycle carbon emissions in 2020, respectively. Implementing fast RE and EV development pathways in the North, Northeast, and Northwest power grid regions (where emissions are mainly from vehicle use and the energy supply chains) while maintaining baseline pathways in Central, East, and South could reduce national life cycle carbon dioxide (CO₂) emissions from 2,186 Mt in 2020 to 1,486 Mt in 2050. Conversely, focusing on fast RE and EV development in the Central, East, and South regions, where vehicle and battery production is mainly located, would only reduce emissions to 1,901 Mt by 2050. Our findings suggest that prioritizing synchronized fast RE and EV development at a power grid region level would be more effective than doing so at a national level in reducing the overall life cycle CO₂ emissions from China’s road transport by 2050. Light-duty passenger vehicles, heavy-duty trucks, and light-duty trucks are the main vehicle types contributing to CO₂ emissions in various regional prioritization in vehicle electrification and RE expansion.

Keywords

Life cycle analysis / prioritizing strategies / power grid regions / electric vehicle development pathways / renewable energy expansion pathways / carbon emissions / road transport sector / China

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Xiang Li, Xiaoyu Yan. Regional prioritization in vehicle electrification and renewable electricity expansion facilitates decarbonization of China’s road transport. Carbon Footprints, 2025, 4(4): 32 DOI:10.20517/cf.2025.47

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