Investigating the impact of high-altitude on vehicle carbon emissions: A comprehensive on-road driving study

This study addresses the literature gap concerning accurately identifying vehicle carbon emission characteristics in high-altitude areas. Utilizing a portable emission measurement system (PEMS) for real-world testing, we quantified the influence of altitude on carbon emissions from light-duty gasoli...

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Bibliographic Details
Published in:The Science of the total environment 2024-03, Vol.918, p.170671-170671, Article 170671
Main Authors: Jiang, Zhiwen, Wu, Lin, Niu, Haomiao, Jia, Zhenyu, Qi, Zhaoyu, Liu, Yan, Zhang, Qijun, Wang, Ting, Peng, Jianfei, Mao, Hongjun
Format: Article
Language:English
Subjects:
High altitude
Machine learning
PEMS
Vehicle carbon emission
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Summary:This study addresses the literature gap concerning accurately identifying vehicle carbon emission characteristics in high-altitude areas. Utilizing a portable emission measurement system (PEMS) for real-world testing, we quantified the influence of altitude on carbon emissions from light-duty gasoline (LDGV) and diesel vehicles (LDDV). The Random Forest (RF) algorithm was employed to analyze the complex nonlinear relationships between altitude, meteorological conditions, driving patterns, and carbon dioxide (CO2) emissions, enabling predictions across different altitudes. The results showed that CO2 emissions progressively increase with elevation. Furthermore, as altitude increases, combustion efficiency declines, and the overall impact of driving conditions on emission rates diminishes. Altitude and meteorological factors significantly contributed to CO2 emissions, whereas driving conditions and road grades contributed less. Compared with the COPERT model, the RF model demonstrates strong accuracy in predicting carbon emissions at different altitudes. Specifically, the CO2 emission rate nearly triples as altitude increases from 2.0 km to 4.5 km. This research bridges a critical gap in the understanding carbon emissions from high-altitude vehicles, offering insights into policy development for emission reduction strategies in such regions. Future studies should integrate diverse testing methodologies and comprehensive surveys to validate and extend the findings. [Display omitted] •CO2 emissions triple approximately with altitude from 2.0 to 4.5 km.•Altitude reduces the impact of driving conditions on emission rates.•Enhanced insights into high-altitude vehicle CO2 emissions through random forest.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.170671