Comparison of Global Downscaled Versus Bottom‐Up Fossil Fuel CO2 Emissions at the Urban Scale in Four U.S. Urban Areas
Gurney, Kevin R.; Liang, J.; O’Keeffe, D.; Patarasuk, R.; Hutchins, M.; Huang, J.; Rao, P.; Song, Y.
2019-03-16
Citation
Gurney, Kevin R.; Liang, J.; O’Keeffe, D.; Patarasuk, R.; Hutchins, M.; Huang, J.; Rao, P.; Song, Y. (2019). "Comparison of Global Downscaled Versus Bottom‐Up Fossil Fuel CO2 Emissions at the Urban Scale in Four U.S. Urban Areas." Journal of Geophysical Research: Atmospheres 124(5): 2823-2840.
Abstract
Spatiotemporally resolved urban fossil fuel CO2 (FFCO2) emissions are critical to urban carbon cycle research and urban climate policy. Two general scientific approaches have been taken to estimate spatiotemporally explicit urban FFCO2 fluxes, referred to here as “downscaling” and “bottom‐up.” Bottom‐up approaches can specifically characterize the CO2‐emitting infrastructure in cities but are labor‐intensive to build and currently available in few U.S. cities. Downscaling approaches, often available globally, require proxy information to allocate or distribute emissions resulting in additional uncertainty. We present a comparison of a downscaled FFCO2 emission data product (Open‐source Data Inventory for Anthropogenic CO2 (ODIAC)) to a bottom‐up estimate (Hestia) in four U.S. urban areas in an effort to better isolate and understand differences between the approaches. We find whole‐city differences ranging from −1.5% (Los Angeles Basin) to +20.8% (Salt Lake City). At the 1 km × 1 km spatial scale, comparisons reveal a low‐emission limit in ODIAC driven by saturation of the nighttime light spatial proxy. At this resolution, the median difference between the two approaches ranged from 47 to 84% depending upon city with correlations ranging from 0.34 to 0.68. The largest discrepancies were found for large point sources and the on‐road sector, suggesting that downscaled FFCO2 data products could be improved by incorporating independent large point‐source estimates and estimating on‐road sources with a relevant spatial surrogate. Progressively coarsening the spatial resolution improves agreement but greater than approximately 25 km2, there were diminishing returns to agreement suggesting a practical resolution when using downscaled approaches.Plain Language SummaryComparison of greenhouse gas emission approaches using globally available data in specific cities shows large differences when compared to greenhouse gas emission approaches constructed from local data sources. Differences are largest at the smaller scales compared to the whole city. This suggests a limit on the use of global greenhouse gas inventories when applied to urban areas.Key PointsThe difference between the global downscaled and bottom‐up estimates for the whole‐city domain exceeds 10% in three of the four citiesAverage grid cell FFCO2 differences at 1‐km2 range from 47% (Salt Lake City) to 84% (LA Basin) with spatial correlations of 0.34 to 0.68Average grid cell FFCO2 differences show diminishing agreement improvements when resolution is coarsened beyond 25 km2Publisher
Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, U.S. Department of Energy Wiley Periodicals, Inc.
ISSN
2169-897X 2169-8996
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