Now showing 1 - 2 of 2
  • Publication
    Metadata only
    Validating the Nernst–Planck transport model under reaction-driven flow conditions using RetroPy v1.0
    (2023-08-24)
    Huang, Po-Wei
    ;
    Flemisch, Bernd
    ;
    Qin, Chao-Zhong
    ;
    Saar, Martin O.
    ;
  • Publication
    Metadata only
    Relating Darcy-Scale Chemical Reaction Order to Pore-Scale Spatial Heterogeneity
    (2022-09-01)
    Huang, Po Wei
    ;
    Flemisch, Bernd
    ;
    Qin, Chao Zhong
    ;
    Saar, Martin O.
    ;
    Due to spatial scaling effects, there is a discrepancy in mineral dissolution rates measured at different spatial scales. Many reasons for this spatial scaling effect can be given. We investigate one such reason, i.e., how pore-scale spatial heterogeneity in porous media affects overall mineral dissolution rates. Using the bundle-of-tubes model as an analogy for porous media, we show that the Darcy-scale reaction order increases as the statistical similarity between the pore sizes and the effective-surface-area ratio of the porous sample decreases. The analytical results quantify mineral spatial heterogeneity using the Darcy-scale reaction order and give a mechanistic explanation to the usage of reaction order in Darcy-scale modeling. The relation is used as a constitutive relation of reactive transport at the Darcy scale. We test the constitutive relation by simulating flow-through experiments. The proposed constitutive relation is able to model the solute breakthrough curve of the simulations. Our results imply that we can infer mineral spatial heterogeneity of a porous media using measured solute concentration over time in a flow-through dissolution experiment.