2025-11-03 カリフォルニア大学アーバイン校(UCI)
<関連情報>
- https://news.uci.edu/2025/11/03/uc-irvine-scientists-devise-method-for-cities-to-measure-greenhouse-gas-emissions/
- https://agupubs.onlinelibrary.wiley.com/doi/10.1029/2025JD043336
芝生の放射性炭素分析による都市部と農村部における化石燃料によるCO2増加の定量化 Quantifying Fossil Fuel CO2 Enhancements Along an Urban-Rural Gradient With Radiocarbon Analysis of Turfgrasses
C. C. Yañez, M. K. Dubey, F. M. Hopkins, A. G. Meyer, X. Xu, J. Romero, J. Kim, H. Parker, C. I. Czimczik
Journal of Geophysical Research: Atmospheres Published: 27 October 2025
DOI:https://doi.org/10.1029/2025JD043336
Abstract
Atmospheric measurements are needed to verify progress in reducing fossil fuel carbon dioxide (ffCO2) emissions, especially in cities where most ffCO2 is emitted. However, measurements of CO2 enhancements alone cannot identify ffCO2 signals due to complexities in atmospheric dynamics and large natural CO2 fluxes. Analysis of the radiocarbon (14C) content of urban annual plants can reveal ffCO2 patterns and is more cost-effective than air 14CO2 sampling, but its use has been limited because of uncertainty in the temporal integration period and because it has not been quantitatively evaluated against other approaches. Here, we analyze the 14C content of managed perennial turfgrasses collected along an urban to rural gradient in the Greater Los Angeles area. We compare the turfgrass 14C to measurements of surface CO2 and total column CO2 (XCO2). We find that turfgrass 14C is highly sensitive to local ffCO2 emissions at the intra-city scale and captures pronounced differences between urban to rural sites. Despite their different atmospheric footprints, we observe significant correlations between fossil fuel enhancements (Cff) derived from turfgrass 14C and total CO2 enhancements from atmospheric CO2 measurements. Furthermore, we combine the turfgrass 14C and surface CO2 measurements to quantify the portion of excess CO2 attributable to biospheric fluxes (Cbio). We find that the turfgrass 14C is dominated by a fossil fuel signal and shows minimal influence of biogenic CO2 fluxes. We show that turfgrass 14C analysis can become a useful tool for quantifying ffCO2 trends in cities that lack permanent surface CO2 and XCO2 measurement infrastructure.
