English

Spatio-temporal bivariate statistical models for atmospheric trace-gas inversion

Applications 2016-09-29 v2

Abstract

Atmospheric trace-gas inversion refers to any technique used to predict spatial and temporal fluxes using mole-fraction measurements and atmospheric simulations obtained from computer models. Studies to date are most often of a data-assimilation flavour, which implicitly consider univariate statistical models with the flux as the variate of interest. This univariate approach typically assumes that the flux field is either a spatially correlated Gaussian process or a spatially uncorrelated non-Gaussian process with prior expectation fixed using flux inventories (e.g., NAEI or EDGAR in Europe). Here, we extend this approach in three ways. First, we develop a bivariate model for the mole-fraction field and the flux field. The bivariate approach allows optimal prediction of both the flux field and the mole-fraction field, and it leads to significant computational savings over the univariate approach. Second, we employ a lognormal spatial process for the flux field that captures both the lognormal characteristics of the flux field (when appropriate) and its spatial dependence. Third, we propose a new, geostatistical approach to incorporate the flux inventories in our updates, such that the posterior spatial distribution of the flux field is predominantly data-driven. The approach is illustrated on a case study of methane (CH4_4) emissions in the United Kingdom and Ireland.

Keywords

Cite

@article{arxiv.1509.00915,
  title  = {Spatio-temporal bivariate statistical models for atmospheric trace-gas inversion},
  author = {Andrew Zammit-Mangion and Noel Cressie and Anita L. Ganesan and Simon O' Doherty and Alistair J. Manning},
  journal= {arXiv preprint arXiv:1509.00915},
  year   = {2016}
}

Comments

39 pages, 8 figures

R2 v1 2026-06-22T10:47:59.041Z