Abstract
Abstract. Geological heterogeneity enhances spreading of solutes and causes transport to be anomalous (i.e., non-Fickian), with much less mixing than suggested by dispersion. This implies that modeling transport requires adopting either stochastic approaches that model heterogeneity explicitly or effective transport formulations that acknowledge the effects of heterogeneity. A number of such formulations have been developed and tested as upscaled representations of enhanced spreading. However, their ability to represent mixing has not been formally tested, which is required for proper reproduction of chemical reactions and which motivates our work. We propose that, for an effective transport formulation to be considered a valid representation of transport through heterogeneous porous media (HPM), it should honor mean advection, mixing and spreading. It should also be flexible enough to be applicable to real problems. We test the capacity of the multi-rate mass transfer (MRMT) model to reproduce mixing observed in HPM, as represented by the classical multi-Gaussian log-permeability field with a Gaussian correlation pattern. Non-dispersive mixing comes from heterogeneity structures in the concentration fields that are not captured by macrodispersion. These fine structures limit mixing initially, but eventually enhance it. Numerical results show that, relative to HPM, MRMT models display a much stronger memory of initial conditions on mixing than on dispersion because of the sensitivity of the mixing state to the actual values of concentration. Because MRMT does not restitute the local concentration structures, it induces smaller non-dispersive mixing than HPM. However long-lived trapping in the immobile zones may sustain the deviation from dispersive mixing over much longer times. While spreading can be well captured by MRMT models, in general non-dispersive mixing cannot.
Highlights
Transport is anomalous in heterogeneous porous media
We test the capacity of the multi-rate mass transfer (MRMT) model to reproduce mixing observed in heterogeneous porous media (HPM), as represented by the classical multi-Gaussian log-permeability field with a Gaussian correlation pattern
As dispersivity is an increasing function of the residence times. This imposes a condition on the temporal range of t1, tN or equivalently on their mean residence time τMRMT
Summary
Transport is anomalous in heterogeneous porous media. Anomalous transport observations include tailing in concentration breakthrough curves and plumes, or the strong increase in the rate of spreading of plumes. We argue that an effective transport formulation should honor the mean advection, and spreading observed in heterogeneous porous media (HPM), and the evolution of mixing This should not be understood as limiting anomalous transport frameworks but as extending them to handle broader ranges of physical and chemical processes, and at further promoting the approach of effective equations that upscale out the fine-scale structures to retain only their main consequences in terms of transport, reactivity and reactive transport couplings. While this last section depends on the specific choice of the MRMT framework as an equivalent transport model, the comparison methodology is independent of it and can be used to assess transport equations respecting both spreading and mixing
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