Trajectories as Training Images to Simulate Advective‐Diffusive, Non‐Fickian Transport

Most, Sebastian; Bolster, Diogo; Bijeljic, Branko; Nowak, Wolfgang

doi:10.1029/2018wr023552

“…Why would we like to consider all these different processes for spatio-temporal phenomena? Just like for temporal processes, understanding processes with a certain large frequency spectral decay, versus boundedness at small frequencies, allows us to understand different types of phenomena, see for example examples such as cyclones and more complex advection and transport [3,21,12,32,23,6,30]. Now to realistically capture that phenomena that dissipate, the author of [9, p. 396] proposed covariance functions with elliptical contours.…”

Section: Homogeneous Traveling Phenomenamentioning

confidence: 99%

“…The fundamental way 3-dimensional space and 2+1dimensional space-time are different is that isotropy is a natural null model in the former scenario, but not at all in the latter scenario. A number of applied studies contain features that require new methodology, such as cyclones and more complex advection and transport [3,21,12,32,23,6,30]. These do require models able to capture more than a strict frozen field model.…”

Section: Introductionmentioning

confidence: 99%

Flexible and Efficient Simulation of Spatio-Temporal Processes with Advection

Battagliola¹,

Olhede²

2023

Preprint

0

View full text Add to dashboard Cite

Traveling phenomena are prevalent in a variety of fields, from atmospheric science to seismography and oceanography. However, there are two main shortcomings in the current literature: the lack of realistic modeling tools and the prohibitive computational costs for grid resolutions useful for data applications. We propose a flexible simulation method for traveling phenomena. To our knowledge, ours is the first method that is able to simulate extensions of the classical frozen field, which only involves one deterministic velocity, to a combination of velocities with random components, either in translation, rotation or both, as well as to velocity fields pointwise varying with space and time. We study extensions of the frozen field by relaxing constraints on its spectrum as well, giving rise to still stationary but more realistic traveling phenomena. Moreover, our proposed method is characterized by a lower computational complexity than the one required for circulant embedding, one of the most commonly employed simulation methods for Gaussian random fields, in R 2+1 .

show abstract

“…In this work, we pursue this objective with the aim of opening new pathways for the application of SMM approaches to transport in porous media at laboratory and field scales. To achieve this goal, our work starts from that of Sund et al (2017), Sherman et al (2019), andMost et al (2019) where a trajectory-based SMM (here labeled tSMM) was formulated. The methodology relies on a set of numerically simulated Lagrangian trajectories obtained for a single unit cell of the porous medium, which is then used to predict transport across much larger distances.…”

Section: 1029/2020wr028408mentioning

confidence: 99%

Upscaling of solute plumes in periodic porous media through a trajectory based spatial Markov model

Janetti

¹

,

Sherman

²

,

Guédon

³

et al. 2020

Preprint

Self Cite

0

View full text Add to dashboard Cite

We propose an approach to upscale solute transport in spatially periodic porous media. Our methodology relies on pore-scale information to predict large-scale transport features, including explicit reconstruction of the solute plume, breakthrough curves at fixed distances, and spatial spreading transverse to the main flow direction. The proposed approach is grounded on the recently proposed trajectory-based spatial Markov model (tSMM), which upscales transport based on information collected from advective-diffusive particle trajectories across one periodic element. In previous works, this model has been applied solely to one-dimensional transport in a single periodic pore geometry. In this work we extend the tSMM to the prediction of multidimensional solute plumes. This is obtained by analyzing the joint space-time probability distribution associated with discrete particles, as yielded by the tSMM. By comparing numerical results from fully resolved simulations and predictions obtained with the tSMM over a wide range of Péclet numbers, we demonstrate that the proposed approach is suitable for modeling transport of conservative and linearly decaying solute species in a realistic pore space and showcase the applicability of the model to predict steady-state solute plumes. Additionally, we evaluate the model performance as a function of numerical parameters employed in the tSMM parameterization.

show abstract

“…In this work, we pursue this objective with the aim of opening new pathways for the application of SMM approaches to transport in porous media at laboratory and field scales. To achieve this goal, our work starts from that of Sund et al (2017), Sherman et al (2019), and Most et al (2019) where a trajectory‐based SMM (here labeled tSMM) was formulated. The methodology relies on a set of numerically simulated Lagrangian trajectories obtained for a single unit cell of the porous medium, which is then used to predict transport across much larger distances.…”

Section: Introductionmentioning

confidence: 99%

Upscaling of Solute Plumes in Periodic Porous Media Through a Trajectory‐Based Spatial Markov Model

Janetti

¹

,

Sherman

²

,

Guédon

³

et al. 2020

Water Resources Research

Self Cite

View full text Add to dashboard Cite

We propose an approach to upscale solute transport in spatially periodic porous media. Our methodology relies on pore-scale information to predict large-scale transport features, including explicit reconstruction of the solute plume, breakthrough curves at fixed distances, and spatial spreading transverse to the main flow direction. The proposed approach is grounded on the recently proposed trajectory-based spatial Markov model (tSMM), which upscales transport based on information collected from advective-diffusive particle trajectories across one periodic element. In previous works, this model has been applied solely to one-dimensional transport in a single periodic pore geometry. In this work we extend the tSMM to the prediction of multidimensional solute plumes. This is obtained by analyzing the joint space-time probability distribution associated with discrete particles, as yielded by the tSMM. By comparing numerical results from fully resolved simulations and predictions obtained with the tSMM over a wide range of Péclet numbers, we demonstrate that the proposed approach is suitable for modeling transport of conservative and linearly decaying solute species in a realistic pore space and showcase the applicability of the model to predict steady-state solute plumes. Additionally, we evaluate the model performance as a function of numerical parameters employed in the tSMM parameterization.

show abstract

Trajectories as Training Images to Simulate Advective‐Diffusive, Non‐Fickian Transport

Cited by 7 publications

References 59 publications

Flexible and Efficient Simulation of Spatio-Temporal Processes with Advection

Flexible and Efficient Simulation of Spatio-Temporal Processes with Advection

Upscaling of solute plumes in periodic porous media through a trajectory based spatial Markov model

Upscaling of Solute Plumes in Periodic Porous Media Through a Trajectory‐Based Spatial Markov Model

Contact Info

Product

Resources

About