@article{27881,
  keywords = {Atmospheric transport, Methane, Greenhouse gas (GHG), Emission inventory, Inverse Model},
  author = {Seongeun Jeong and Sally Newman and Jingsong Zhang and Arlyn E Andrews and Laura Bianco and Justin Bagley and Xinguang Cui and Heather Graven and Jooil Kim and Peter Salameh and Brian W LaFranchi and Chad Priest and Mixtli Campos-Pineda and Elena Novakovskaia and Christopher D Sloop and Hope A Michelsen and Ray P Bambha and Ray F Weiss and Ralph Keeling and Marc L Fischer},
  title = {Estimating methane emissions in California's urban and rural regions using multitower observations},
  abstract = {<p>We present an analysis of methane (CH<sub>4</sub>) emissions using atmospheric observations from 13 sites in California during June 2013 to May 2014. A hierarchical Bayesian inversion method is used to estimate CH<sub>4</sub>&nbsp;emissions for spatial regions (0.3° pixels for major regions) by comparing measured CH<sub>4</sub>mixing ratios with transport model (Weather Research and Forecasting and Stochastic Time-Inverted Lagrangian Transport) predictions based on seasonally varying California-specific CH<sub>4</sub>&nbsp;prior emission models. The transport model is assessed using a combination of meteorological and carbon monoxide (CO) measurements coupled with the gridded California Air Resources Board (CARB) CO emission inventory. The hierarchical Bayesian inversion suggests that state annual anthropogenic CH<sub>4</sub>&nbsp;emissions are 2.42&thinsp;±&thinsp;0.49&thinsp;Tg&thinsp;CH<sub>4</sub>/yr (at 95% confidence), higher (1.2–1.8 times) than the current CARB inventory (1.64&thinsp;Tg&thinsp;CH<sub>4</sub>/yr in 2013). It should be noted that undiagnosed sources of errors or uncaptured errors in the model-measurement mismatch covariance may increase these uncertainty bounds beyond that indicated here. The CH<sub>4</sub>emissions from the Central Valley and urban regions (San Francisco Bay and South Coast Air Basins) account for ~58% and 26% of the total posterior emissions, respectively. This study suggests that the livestock sector is likely the major contributor to the state total CH<sub>4</sub>&nbsp;emissions, in agreement with CARB's inventory. Attribution to source sectors for subregions of California using additional trace gas species would further improve the quantification of California's CH<sub>4</sub>&nbsp;emissions and mitigation efforts toward the California Global Warming Solutions Act of 2006 (Assembly Bill 32).</p>},
  year = {2016},
  journal = {Journal of Geophysical Research: Atmospheres},
  volume = {121},
  month = {11/2016},
  doi = {10.1002/2016JD025404},
}