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Estimating changes in urban ozone concentrations due to life cycle emissions from hydrogen transportation systems

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  • Wang, Guihua
  • Ogden, Joan M
  • Chang, Daniel P.Y.

Abstract

Hydrogen has been proposed as a low polluting alternative transportation fuel that could help improve urban air quality. This paper examines the potential impact of introducing a hydrogen-based transportation system on urban ambient ozone concentrations. This paper considers two scenarios, where significant numbers of new hydrogen vehicles are added to a constant number of gasoline vehicles. In our scenarios hydrogen fuel cell vehicles (HFCVs) are introduced in Sacramento, California at market penetrations of 9% and 20%. From a life cycle analysis (LCA) perspective, considering all the emissions involved in producing, transporting, and using hydrogen, this research compares three hypothetical natural gas to hydrogen pathways: (1) on-site hydrogen production; (2) central hydrogen production with pipeline delivery; and (3) central hydrogen production with liquid hydrogen truck delivery. Using a regression model, this research shows that the daily maximum temperature correlates well with atmospheric ozone formation. However, increases in initial VOC and NOx concentrations do not necessarily increase the peak ozone concentration, and may even cause it to decrease. It is found that ozone formation is generally limited by NOx in the summer and is mostly limited by VOC in the fall in Sacramento. Of the three hydrogen pathways, the truck delivery pathway contributes the most to ozone precursor emissions. Ozone precursor emissions from the truck pathway at 9% market penetration can cause additional 3-h average VOC (or NOx) concentrations up to approximately 0.05% (or 1%) of current pollution levels, and at 20% market penetration up to approximately 0.1% (or 2%) of current pollution levels. However, all of the hydrogen pathways would result in very small (either negative or positive) changes in ozone air quality. In some cases they will result in worse ozone air quality (mostly in July, August, and September), and in some cases they will result in better ozone air quality (mostly in October). The truck pathway tends to cause a much wider fluctuation in degradation or improvement of ozone air quality: percentage changes in peak ozone concentrations are approximately −0.01% to 0.04% for the assumed 9% market penetration, and approximately −0.03% to 0.1% for the 20% market penetration. Moreover, the 20% on-site pathway occasionally results in a decrease of about −0.1% of baseline ozone pollution. Compared to the current ambient pollution level, all three hydrogen pathways are unlikely to cause a serious ozone problem for market penetration levels of HFCVs in the 9–20% range.

Suggested Citation

  • Wang, Guihua & Ogden, Joan M & Chang, Daniel P.Y., 2007. "Estimating changes in urban ozone concentrations due to life cycle emissions from hydrogen transportation systems," Institute of Transportation Studies, Working Paper Series qt21c6p765, Institute of Transportation Studies, UC Davis.
    • Handle: RePEc:cdl:itsdav:qt21c6p765
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    1. Delucchi, Mark A. & Murphy, James & Kim, Jin & McCubbin, Donald R., 1996. "The Cost of Crop Damage Caused by Ozone Air Pollution From Motor Vehicles," University of California Transportation Center, Working Papers qt1j6730td, University of California Transportation Center.
    2. Delucchi, Mark, 2005. "A Multi-Country Analysis of Lifecycle Emissions From Transportation Fuels and Motor Vehicles," Institute of Transportation Studies, Working Paper Series qt8nf3606c, Institute of Transportation Studies, UC Davis.
    3. Delucchi, Mark A. & Murphy, James & Kim, Jin & McCubbin, Donald R., 1996. "The Cost of Crop Damage Caused by Ozone Air Pollution From Motor Vehicles," University of California Transportation Center, Working Papers qt1j6730td, University of California Transportation Center.
    4. Wang, Guihua & Ogden, Joan M & Nicholas, Michael A, 2007. "Lifecycle impacts of natural gas to hydrogen pathways on urban air quality," Institute of Transportation Studies, Working Paper Series qt4fs2b9bv, Institute of Transportation Studies, UC Davis.
    5. Delucchi, Mark, 2005. "A Multi-Country Analysis Of Lifecycle Emissions From Transportation Fuels And Motor Vehicles," Institute of Transportation Studies, Working Paper Series qt5x20v080, Institute of Transportation Studies, UC Davis.
    6. McCubbin, Donald R. & Delucchi, Mark A., 1996. "The Social Cost of the Health Effects of Motor-Vehicle Air Pollution," University of California Transportation Center, Working Papers qt5jm6d2tc, University of California Transportation Center.
    7. Ogden, Joan M. & Williams, Robert H. & Larson, Eric D., 2004. "Societal lifecycle costs of cars with alternative fuels/engines," Energy Policy, Elsevier, vol. 32(1), pages 7-27, January.
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    1. Ercolino, Giuliana & Ashraf, Muhammad A. & Specchia, Vito & Specchia, Stefania, 2015. "Performance evaluation and comparison of fuel processors integrated with PEM fuel cell based on steam or autothermal reforming and on CO preferential oxidation or selective methanation," Applied Energy, Elsevier, vol. 143(C), pages 138-153.
    2. Konstantinos Metaxoglou & Aaron Smith, 2020. "Productivity Spillovers From Pollution Reduction: Reducing Coal Use Increases Crop Yields," American Journal of Agricultural Economics, John Wiley & Sons, vol. 102(1), pages 259-280, January.
    3. Wang, Guihua & Bai, Song & Ogden, Joan M., 2009. "Identifying Contributions of On-road Motor Vehicles to Urban Air Pollution Using Travel Demand Model Data," Institute of Transportation Studies, Working Paper Series qt2700q8x1, Institute of Transportation Studies, UC Davis.
    4. Sperling, Dan & Wang, Guihua & Ogden, Joan M., 2008. "Comparing air quality impacts of hydrogen and gasoline," Institute of Transportation Studies, Working Paper Series qt9215h1m8, Institute of Transportation Studies, UC Davis.

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