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From pore scale to continuum scale modeling of infiltration
Accepted Manuscript
From pore scale to continuum scale modeling of infiltration J. Tzavaras, M. Kohne, H.-J. Vogel ¨ PII: DOI: Reference:
S0309-1708(16)30281-0 10.1016/j.advwatres.2017.03.005 ADWR 2795
To appear in:
Advances in Water Resources
Received date: Revised date: Accepted date:
23 July 2016 15 November 2016 7 March 2017
Please cite this article as: J. Tzavaras, M. Kohne, H.-J. Vogel, From pore scale to continuum scale ¨ modeling of infiltration, Advances in Water Resources (2017), doi: 10.1016/j.advwatres.2017.03.005
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Highlights • pore network model based on cylindrical pores and nodes without spatial extent • implementation of an infiltration process
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• comparison to Richards equation (continuum scale modeling)
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• biconjugate gradient method with pressure field iterations
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From pore scale to continuum scale modeling of infiltration J. Tzavarasa,∗, M. K¨ohnea , H.-J. Vogela Centre for Environmental Research, Theodor-Lieser-Str. 4, 06120 Halle (Saale), Germany
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a UFZ-Helmholtz
Abstract
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Water infiltration in soil at the continuum scale is typically modeled using Richards equation. This requires effective material properties, the water retention characteristic and the unsaturated hydraulic conductivity function. During infiltration the gaseous phase is replaced by water within a complex porous structure. This produces phenomena such as irregular infiltration fronts, hydraulic non-equilibrium and hysteresis which are ultimately related to pore scale processes. In this work we simulate infiltration at the pore scale using a pore network model where the pore structure can be adapted to real structures in terms of pore size distribution and pore topology. We compare the horizontally averaged dynamics of water content and water potential to the results obtained from Richards’ equation. This provides evidence that the pore network representation is consistent with the typical macroscopic dynamics at the continuum scale. However, assuming immiscible and incompressible fluid phases leads to unrealistic gas entrapment in the network model. We conclude that mechanisms leading to a release of trapped gas phase in natural porous media are difficult to represent in a pore network model. Yet, the proposed pore scale approach has the potential to study fundamental relations between pore structure and macroscopic phenomena not only for drainage but also for infiltration.
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1. Introduction
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Keywords: pore network model, pore scale modeling, continuum scale modeling, infiltration, Richards equation
Pore network models (PNMs) have long been used to describe water dynamics in porous media. Based
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Joekar-Niasar and Hassanizadeh [4]. Two-phase flow in a steady state regime was simulated by Constan-
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tinides and Payatakes [5] to predict the macroscopic relative permeabilities, and to relate relative permeabil-
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on the pioneering work of Fatt [1, 2, 3] there is an enormous body of literature mostly dealing with drainage processes (i.e. non-wetting phase replacing wetting phase) and stationary flow. A recent review is given by
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ities to the flow mechanisms at pore level. Wetting process are much more difficult to describe, since the
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dynamics of any individual interface need to be modeled. This can be done by pore scale simulations based
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on Stokes or Navier-Stokes equation to be solved numerically based on Lattice Boltzmann (Ahrenholz et al.
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[6], Porter et al. [7]) or similar approaches. The major drawback is that the pore space need to be explic-
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itly represented within a very limited volume and at a limited resolution. This is why the approach based ∗ Corresponding
author Email addresses: [email protected] (J. Tzavaras), [email protected] (M. K¨ohne), [email protected] (H.-J. Vogel)
Preprint submitted to Elsevier
July 2016
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on Navier-Stokes equation is typically applied to mono-scale porous media as sand or sandstone where the
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relevant pore structure can be captured within a few cubic millimeters. To overcome this problem, Yang
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et al. [8] added a Darcy-term to represent flow in the porous matrix. In this way, smaller pores that are not
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wetting process is difficult to compute. Wetting processes, especially infiltration into relatively dry soil leads
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to macroscopic phenomena as hydraulic non-equilibrium or hysteresis which are relevant for the redistribu-
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tion of precipitation water in soil and which are deemed to be explained by effects of heterogeneities at the
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pore scale. In petroleum engineering this is a highly relevant problem for replacing oil by water.
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explicitly represented for solving Navier-Stokes equation could be represented. A pore network model as used in our study offers the possibility to represent more complex structures as typical for soils, however the
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In contrast to static drainage processes, the simulation of infiltration into network models is challenging
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since the pressure distribution has to be recalculated after each change in fluid saturation to correctly repre-
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sent the final fluid configuration at equilibrium. Solution to this problem has been provided by Mogensen
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and Stenby [9] and was more thoroughly described and elaborated in Mogensen et al. [10] who introduced
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an iterative method to recalculate the pressure field after each time step of infiltration. More recently another
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approach was presented by Tørå et al. [11] who expanded the solution for two-phase flow in a pore network
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model to imbibition, drainage and steady state displacement.
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In our paper we apply the concept of Mogensen et al. [10] to water infiltration in soil. Our pore network
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model (PNM) is based on straight cylindrical pores connected to nodes without spatial extent. The main
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motivation is to explore if the pore scale description is consistent with continuum scale models in terms of
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the macroscopic dynamics of hydraulic state variables, i.e. water content and water potential.
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2. Pore scale modeling
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2.1. Network generation
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To generate a realistic pore network model (PNM) we use the concept introduced by Vogel and Roth
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[12]. Thereby, relevant structural properties as pore size distribution and pore topology can be preserved
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while less relevant details such as surface roughness are simplified. The PNM is based on a face-centered
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cubic grid (coordination number 12) with cylindrical bonds representing pores while the nodes have zero
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volume. Pore size distribution and pore topology are adjusted to measured values as obtained from 3D
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CT images. To represent the measured pore geometry only a small part of the 12 possible bonds per node
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are required so that the effective coordination number Zeff is smaller than Zmax = 12. In contrast to other
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approaches where bonds are removed by some random or regular process (Raoof and Hassanizadeh [13])
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we build up the network starting from the largest pores so that the Euler number of each pore size class as
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measured in the CT images is reproduced. A special feature of our network model is that the remaining
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bonds (i.e. Zmax − Zeff ) are considered as “background porosity”. This accounts for the fact that in soil
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there are always small pores that are not resolved by the imaging technique (CT). The resolution of CT
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images is at best 0.01 mm while clay particles in soil are much smaller. As a consequence, these small pores
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cannot be represented in the network of discrete pores, however, they definitely contribute to water flow. 2
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pore diameter EPC (str.) EPC (ran.)
0.04 -34.49 -45.37
0.066 -1.92 -5.61
0.092 -0.01 1.57
0.118 0.47 3.69
0.144 0.37 2.65
0.169 0.39 1.66
0.207 0.27 1.05
0.253 0.24 0.88
0.299 0.15 0.67
0.345 0.08 0.54
Table 1: Pore diameter and measured Euler Numbers for the structured and random PNM.
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With adding this background porosity described by some mean pore size smaller than the other pores in the PNM, this effect is accounted for. In this way also the water phase is always continuous reflecting the natural
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situation of moist soil. In other PNMs this important feature is obtained by using angular pores (Raoof and
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Hassanizadeh [14], Joekar-Niasar and Hassanizadeh [4]). The background porosity was assigned a small
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pore diameter dmin = 0.007 mm. This value is considerably smaller than the pores resolved by CT (0.04
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mm) and was chosen such that the unsaturated conductivity attains realistic values.
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The pore size distribution and the pore topology was adapted to a loess soil which has already been studied by Vogel [15]. We generate a ’structured PNM’ taking account of the measured topology and a ’random PNM’ where the same pores with the same size distribution are connected randomly. The structured
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and the random grid both have a size of 16 × 16 × 32 nodes. These dimensions are large enough so that the
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simulations converged to stable results while they are yet small enough to be numerically tractable. The pore
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size distribution is represented by ten discrete pore size classes. In Table 1 the pore diameters and measured
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Euler Numbers for the two different PNMs are listed. The definition of the specific Euler number χV referred
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to as EPC in Table 1 is given by:
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N +C −H (1) V It is based on the fundamental topological properties of a volume V, which are the number of isolated
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objects N, the number of redundant connections or loops C often referred to as connectivity or genus and the
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number of completely enclosed cavities H corresponding to hollow spheres (for more details see Vogel and
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Roth [12]).
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χV =
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(results not shown). This corroborates the well known fact that pore topology is critical for infiltration. We
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doubled the coordination number from 2.5 (structured PNM) to 5.0 for the random PNM to increase the pore
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connectivity for the random PNM. As a consequence, the grid constant (i.e. the distance between adjacent
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nodes) was increased from 0.258 mm (structured PNM) to 0.364 mm and the vertical height of the network
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from 5.66 mm to 7.98 mm to represent the same porosity for the given number of nodes.
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When using the same pore size distribution and the same coordination number as for the structured PNM, first simulations indicated that infiltration into the random PNM was blocked due to entrapped gas phase
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2.2. Calculation of flow To calculate water flow within the pore network as a consequence of some external gradient in water
pressure pw we use Kirchhoffs’ law to guarantee the required mass balance at each node i:
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qi j = 0
(2)
j=1
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where qi j is the volumetric flow in the pore connecting the nodes i and j, in the following referred to as pore i j. The pressure in the water phase pw is related to the capillary potential pc as follows: pc = pw − pa
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defined as the sum of capillary potential pc and gravitational potential pg :
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The gravitational potential is given by
pg = ρw gh
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(3)
The driving force for vertical infiltration into the porous network is the total hydraulic potential ψw
ψw = pc + pg 81
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(4)
(5)
with ρw [ML−3 ] the density of water, g [LT −2 ] the gravitational acceleration and h [L] the height above the lower boundary of the network.
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During transient conditions we need to distinguish three different configurations of phase distribution within an individual pore to calculate qi j : i) completely water saturated, ii) completely gas saturated or iii)
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partially filled with both phases (i.e. the pore is in the state of infiltration).
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For water-filled pores (see Fig. 1a)) the flow is obtained by:
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qi j = Gi j (ψw,i − ψw, j ),
where the hydraulic conductivity Gi j is given by:
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(6)
Gi j =
πri4j 8η
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with ri j the radius of the pore i j and η the viscosity. We assume complete wettability of the solid surfaces.
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During infiltration gas-filled pores are gradually invaded by water. Water can invade a pore with radius ri j from node i (see Fig. 1b)) if and only if all of the following requirements are met:
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ρw gλi j 1. pc,i + α √ > − 2σ ri j 2 2. There is no water entering from the opposite side of the pore.
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3. There is a continuous air path from the neighboring node j to the upper or lower boundary of the model.
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4. No water has entered the pore and ψw,i ≥ ψw, j or the pore is already partly filled.
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As described in condition 1, the capillary pressure at node i needs to exceed the entry pressure of a given pore described by the Young-Laplace equation. Once the pore is already partially water-filled with a length λi j [L] an additional gravitational component for the water column inside the pore needs to be considered. The weight factor α accounts for the direction of filling, α = {1, 0, −1} for downward, horizontal or upward flow respectively.
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During infiltration of a pore the local flow is described by:
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! ρw gλi j 2σ qi j = Gmin (ψw,i − ψw, j ) + Gi j pc,i + α √ + (8) ri j 2 The first term represents water flow along the walls of gas-filled pores. The corresponding conductivity
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Gmin is set to the same value as the background porosity. Such a wall flow is a reasonable assumption
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and, moreover, it renders the numerical calculation of the pressure field more stable. For the second term
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describing the pore filling only the capillary potential and not the total hydraulic potential is taken into
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account because the driving force of the filling process is independent from the gravitational potential at
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node i. The condition under which a pore is to be filled is the same for all the pores irrespective of their
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height.
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For gas-filled and partially filled pores in which bulk flow is not taking place and for ’background porosity’ (see Fig. 1c)) we assume a small water-filled radius rmin so that
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qi j = Gmin (ψw,i − ψw, j )
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with
Gmin =
4 πrmin 8η
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After infiltration of a given pore, the continuity of the air phase to the lower and upper boundary is
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(9)
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updated for each node in the network so that condition 3 can be easily checked in the following time steps.
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2.3. Initial and boundary conditions Initially the capillary potential is set to a fixed value within the entire network which mimics stationary
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gravity flow at this potential. The initial water saturation corresponds to the volume of pores that are water
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filled at this potential. To simulate infiltration we impose a higher but fixed capillary potential at the inlet
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nodes of the upper boundary. At the lower boundary a gravitational pressure gradient is applied. This is es-
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tablished by setting the capillary potential at the nodes of the lower boundary equal to the values of the nodes
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in the second lowest layer. However, this procedure leads to artifacts in case that the hydraulic conductivity
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of the lower layer (i.e. the bonds between the lowest and the second lowest nodes) is higher compared to
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the layer above. In this case, the reduced water potential in the second lowest level, which was set equal to
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the lowest level, induces a feedback so that gravity flow conditions (i.e. a constant matric potential along the
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vertical axis) are not reached. We solved this problem by changing the pore size distribution of the lower
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level such that it is smaller than that of the layer above. In this way, the artificial impact of the lower bound-
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ary on the dynamics within the network is minimized to become negligible. The lateral faces are periodic in the horizontal plane to prevent undesired boundary effects.
a)
b)
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qi2
qi1
i
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qij
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qi3
λij
qij
c)
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qij
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qij
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Figure 1: Rule based filling mechanisms: a) example for mechanism of water filled pores with bulk flow possible b) example for mechanism of the gradually filling of a gas-filled pore c) examples for mechanism of gas-filled and partly filled pores in which bulk flow is not possible and there exist only flow along the ’background porosity’. Left: pressure level at node i insufficient to fill adjacent bigger pores, right: no bulk flow in pore i j due to entrapped air 131
2.4. Dynamics of infiltration
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Infiltration was initiated by setting the matric potential at the uppermost nodes, pc,inlet to some value
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above the current state of the network. In a first step all bonds connected to the upper boundary nodes where
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ri, j ≥ 2σ/pc,inlet are filled with water. In the following, the dynamics of moving water/air interfaces were 6
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calculated by updating the pressure field and then using the rule based filling conditions after each time-step
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to calculate fluxes and update water saturation at each pore. The dynamic time-steps are defined by the
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actual time required to fill the next pore completely. This time-step is calculated with respect to all pores i j
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containing a moving interface: (
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For the entire network the flow balance system can be formulated in matrix notation as: A(p)p = b(p)
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(11)
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) Va,i j tmin = min qi j Here Va,i j is the air-filled volume of a pore i j and qi j is the flow of the wetting phase into it.
(12)
where A(p) is the n × n matrix containing the conductivities between n individual nodes Gi j and Gmin .
Note that air-filled pores have a low fixed conductivity Gmin . The vector p contains the unknown pressures
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at the nodes, b is the vector containing the given pressures at the upper and lower boundaries pinlet and poutlet
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multiplied by the conductances of the bonds connected to these boundaries and the capillary pressures and
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conductances of pores being filled. A biconjugate gradient method was used to solve the resulting system of
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linear equations ( Press et al. [16] ). Following the suggestion of Mogensen et al. [10] the calculation of the
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pressure field was done iteratively by minimizing the function
1 T p Ap − b(p)T p (13) 2 for each time-step. Since f (p) opens upwards and is convex it has an extremum for exactly one vector p
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f (p) =
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which is the global minimum of f (p). This is obtained based on an iterative approach of the form
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A(pk )pk+1 = b(pk ), k = 0, 1, ...
(14)
When the initial vector p0 is chosen to match the pressure solution of the previous time-step, the number of steps required to minimize f (p) was found to be very small. Solving the linear system of equations a stable and fast solver is necessary. In contrast to the method
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suggested by Mogensen and Stenby [9] (conjugate gradient method preconditioned by symmetric succes-
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sive overrelaxation) we used the so called biconjugate gradient method. A mathematical description of the
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method as well as the computer code of the solver is provided by Press et al. [16]. A set of solvers belonging
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to the ITPack software package (FORTRAN code - i.e. Jacobi Conjugate Gradient (JCG), Sucessive Over-
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relaxation (SOR), Symmetric SOR Conjugate Gradient (SSORCG), Reduced System Semi-Iteration (RSSI)
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solver) was also tested and gave very similar results.
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3. Continuum scale modeling
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To model infiltration at the continuum scale we used the classical Richards equation in its one-dimensional
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∂t θ(h) − ∂z K(h)[∂z (h + z)] = 0 162
(15)
where z denotes the vertical coordinate pointing upwards. This equation relies on two hydraulic material
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properties, the water retention curve θ(h) and the unsaturated hydraulic conductivity function K(h). The
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volumetric water content is given by θ [-], K [LT−1 ] denotes the hydraulic conductivity and h [L] is the soil
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matric potential in the form of hydraulic head. The latter is related to capillary pressure by pc = ρw gh. To allow for a direct and consistent comparison between pore scale and the continuum scale simulations
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we obtained both hydraulic functions from simulations of the PNM. This was done for a stepwise wetting
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of the PNM to describe the imbibition branch of the hysteretic functions. According to the ten pore size
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classes of the PNM, this led to 10 discrete points for both functions. For a parametric description of θ(h) we
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fitted a van Genuchten model (van Genuchten [17]) in its bimodal form according to Durner [18] to increase
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flexibility. For the hydraulic conductivity function we fitted a spline to the data points. Note that for the
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scope of this paper it is important to get a good description of the data points simulated by PNM while the
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number of parameters to do so is not critical.
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Finally, based on the parameterized hydraulic functions, Richards equation was solved for the same
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pressure steps as for the PNM using the software package µPhi (Ippisch et al. [19]). This code uses a cell-
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centered finite volume scheme for spatial discretization and the solver is based on an implicit Euler scheme
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in time and a full upwind scheme in space while the time step is adapted automatically.
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4. Results and discussion
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4.1. Effective properties
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For both the structured and random PNM we simulated infiltration in 10 pressure steps. After each step
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we waited for the system to reach hydrodynamic equilibrium (i.e. no changes in local pressures anymore)
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before initiating the next increase in pressure. We started from a drained model with a pressure of -74 hPa
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throughout the model slightly lower than the capillary pressure of the smallest measured pore size class.
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The drainage function which was used to drain the model, was already tested and validated (Vogel and Roth
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[12]). The first infiltration cycle was simulated by setting the pressures at the top plane of the model (upper
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boundary) to a pressure of -44 hPa slightly higher than the capillary pressure of the second smallest pore
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size. During the second step the pressure at the upper boundary was raised to a level of -31 hPa a little bit
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higher than the capillary pressure of the third smallest pore size and so on.
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Combined plots for the simulated hydraulic functions of the structured grid in contrast to the random
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grid are shown in Figs. 2 and 3. The first plot for both models contains the data points of the water content
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over the pressure head obtained by the PNM together with the water retention curve (i.e. capillary pressure saturation relation) as obtained after fitting the van Genuchten parameters of a bimodal model to the output
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data of the PNM. The fitting function of the bimodal model reads:
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Sw =
X
ωi (1 + (αi pc )ni )−(1+1/ni )
(16)
i
Sw = and
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X
θ − θr θ s − θr
(17)
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with the water saturation
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ωi = 1
(18)
i
with S w : water saturation, θ s : water content at saturation, θr : residual water content, α1 , α2 , n1 ,n2 : van
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Genuchten paramters for submaterial 1 and 2, ω: fraction of the submaterial 1 of the total material.
In the second plot the fitted spline interpolation is shown together with the simulated data point for
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hydraulic conductivity. We observe significantly higher hydraulic conductivity values for the random PNM. 0.36 0.355 0.35
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structured PNM: datapoints fit random PNM: datapoints fit
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0.34 0.335 0.33
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water content θ [-]
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0.325
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-50 -40 -30 matric potential pc [hPa]
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-10
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Figure 2: Water retention characteristics simulated by the network Model (symbols) and fitted parameterization (lines) for the structured (blue) and the random PNM (red). The porosity in both networks was fixed to 0.5027
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-1
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log (permeability K) [cm/h]
-0.5
structured PNM: datapoints fit random PNM: datapoints fit
-1.5
-2.5 0.32
0.325
0.33
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0.335 0.34 0.345 water content θ [-]
0.35
0.355
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Figure 3: Hydraulic conductivities simulated by the network Model (symbols) and spline interpolation (lines) for the structured (blue) and the random PNM (red).
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There is a considerable difference in hydraulic properties between the random and the structure PNM although the pore size distributions are identical. This is explained by the different topology of the models
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leading to a different amount of entrapped air within the various pore size classes. This is illustrated in Fig. 4.
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In the structured grid much more air is entrapped in small pores (water filled at pc < 31 hPa) but less in the
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larger pores. This is due to the connectivity of the pores as indicated by the Euler numbers (Tab. 1) with
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lower values for higher connectivity. The connectivity of small pores in the random PNM is increased due
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to the increased coordination number as explained above while the connectivity of larger pores is slightly
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increased in the structured PNM reflecting the connectivity of the natural pore space. This explains the
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different shape of the water retention characteristics.
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The assumption of immiscible fluids leads to a large volume of air entrapments (80-90%) in the larger
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pores (water filled above pc ≥ 31 hPa). Thus, hydraulic conductivity is mainly governed by the two smaller
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pore size classes which are better connected with an increased water saturation within the random PNM. This is why the random PNM exhibits considerably higher conductivities.
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We are aware that the enormous volume of air entrapment is not quite realistic for the original soil
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where pore size and topology was measured. This is rather a consequence of assuming incompressible and
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immiscible fluids and no additional processes such as dissolution of the gas phase and leaking of bubbles
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due to local pressure gradients allowing for fluids to escape once they are trapped. However for the scope of
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this work this is not critical.
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Figure 4: Entrapped air at different capillary potentials. 218
4.2. Infiltration into the pore network models
To compare the results of pore scale with continuum scale infiltration we simulated infiltration into the
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two smallest pore size classes of the PNM. Most of the water infiltrates at these pressure steps due to air
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entrapments in the larger pore size classes. The infiltration process into the entire network from top to the
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bottom is illustrated in Figs. 5 and 6. Qualitatively this confirms the validity of the rule based pore filling
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procedure. The infiltration front in the random PNM is remarkably sharper as compared to the structured
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grid. The reason for this is a more uniform velocity profile due to the random distribution of pores at higher
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coordination number in contrast to the more clustered topology of the structured PNM.
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the behavior of the pore scale properties (i.e. pore size distribution and topology).
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For a reliable interpretation of the results it is crucial that the PNMs are large enough to actually reflect
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Figure 5: The invasive infiltration process with increasing time (left to right) for the structured grid. First pressure step allowing the two smallest pore size classes to be filled consecutively from top to bottom. Air: red, water: blue.
Figure 6: The same illustration as in previous figure for the random grid.
In Fig. 7 pressure profiles during infiltration are shown. The pressure was calculated as an average over
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all nodes within a horizontal plane. The curves are smoother as compared to random PNM (shown in Fig. 8)
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which is due to the sharper infiltration front in the random PNM. Both models converge toward gravity flow
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and dynamic equilibrium at the end of the infiltration process.
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depth z in mm
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-6 -75
t=0s t=0.1s t=0.2s t=0.3s t=0.4s t=0.5s t=0.6s t=0.7s t=0.8s t=0.9s t=1.0s t=1.2s t=1.4s t=1.6s t=1.8s t=2.0s t=2.5s t=3.0s t=3.5s t=4.0s t=5.0s t=6.0s t=7.0s t=8.0s t=10s t=20s t=30s t=600s t=4000s
-70
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-60 -55 matric potential pc in hPa
-50
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Figure 7: Pressure profile for the structured grid. The two vertical red lines indicate the capillary pressure of the smallest (d = 0.04mm) and second smallest (d = 0.066mm) pore sizes, at which the pores of these sizes can be filled.
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Figure 8: The same plot as in previous figure for the random grid.
For a reliable interpretation of the results it is crucial that the PNMs are large enough so that the observed
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behavior can actually be related to the pore scale attributes (i.e. pore size distribution and topology). To
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demonstrate in how far this can be done, we simulated 5 different realizations for both, the structured and
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the random network. The small standard deviation of the pressure profiles of the different realizations clearly suggests that the volume of the networks is large enough to draw some general conclusions (see Fig. 9).
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Figure 9: Comparisons of the pressure profiles of 5 realizations of the structured (above) and random (below) grid plotted for three different times.
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The dynamics of the water content during the same infiltration process is shown in Figs. 10 and 11. It
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was calculated as an average over the bonds connected to all nodes within a horizontal plane. As for the
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pressure the water front infiltrates from top toward the bottom. However, the water content profiles show two
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subsequent waves. First, the smaller pore size class is infiltrated and only when these pores are filled within the entire network the larger pore size class starts to be invaded from the top. This is due to the discrete
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pore size classes having a fixed pore size each. At the bottom, the water content within the lowest layer is increased because the mean pore size in this layer was reduced to avoid boundary effects as explained in
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section 2.3..
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The infiltration dynamics is similar for the structured and the random PNM while the absolute water con-
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tent in the random PNM is somewhat higher because of the increased coordination number of this network.
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Figure 10: Water content profile for the structured grid.
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Figure 11: Water content profile for the random grid.
4.3. Comparison with the continuum model
Starting from the same initial conditions, the same pressure steps as applied for the PNM simulation
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were implemented as boundary conditions for 1D Richards equation. We used the water retention curve and
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the hydraulic conductivity function as shown in Figs. 2 and 3, respectively. To compare the results of the 3D PNM model with those of 1D Richards equation we averaged the water
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potential and the water content in each horizontal layer of the PNM. The results for the structured grid are
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shown in Fig. 12. Overall the infiltration profiles are similar, however, there are mainly two remarkable
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differences. First, the infiltration front within the PNM model is sharper and second, the propagation of the
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pressure front is initially slower in the PNM and accelerates after the tip of the front reached the bottom.
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In contrast, the results of Richards equation are more gradual and smoother in space and time. The random
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PNM (Fig. 13) shows the same behavior but even more pronounced. This is explained by the two discrete
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pore size classes that are invaded in the PNMs. Each pore size class has a fixed pore diameter so that the
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critical pressure to infiltrate the larger pores is only reached after the smaller pores were saturated.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 6s PNM t = 6s Muphi t = 7s PNM t = 7s Muphi t = 8s PNM t = 8s Muphi t = 10s PNM t = 10s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 600s PNM t = 600s Muphi t = 4000s PNM t = 4000s Muphi
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Figure 12: Pressure profile comparison with Richards equation for the structured grid.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 7s PNM t = 7s Muphi t = 122s PNM t = 122s Muphi
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Figure 13: Pressure profile comparison with Richards equation for the random grid.
Comparing the water content profiles in Figs. 14 and 15 clearly demonstrates the consecutive infiltration
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into the two different pore size classes. Individual pores can only be filled in the PNM if the matric potential
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at the node reaches the capillary pressure of these pores. Obviously this critical capillary pressure is only
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reached for the larger pore size class when the smaller pores are already infiltrated at the bottom. This
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leads to the observed stepwise increase in water content and a sharper invasive infiltration front as already
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discussed for the pressure profiles. Since the water retention characteristic used for the continuum scale
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model was obtained from PNM-simulations the water content averaged over the entire domain agrees well
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for the two model concepts. Due to the local heterogeneity within different horizontal planes of the PNM
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the water content profiles observed in the PNM are less smooth.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 6s PNM t = 6s Muphi t = 7s PNM t = 7s Muphi t = 8s PNM t = 8s Muphi t = 10s PNM t = 10s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 600s PNM t = 600s Muphi t = 4000s PNM t = 4000s Muphi
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Figure 14: Water content profile comparison with Richards equation for the structured grid.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 7s PNM t = 7s Muphi t = 10s PNM t = 10s Muphi t = 15s PNM t = 15s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 50s PNM t = 50s Muphi t = 80s PNM t = 80s Muphi t = 122s PNM t = 122s Muphi
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5. Conclusions
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Figure 15: Water content profile comparison with Richards equation for the random grid.
We simulated water infiltration into a 3-dimensional pore network model representing the statistical
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properties of the pore size distribution and the pore connectivity of an undisturbed soil. We compared the
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obtained dynamics of capillary potential and water content to the results of a 1D continuum scale model
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based on Richards equation. For macroscopically homogeneous media the phenomenology of water dy-
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namics can be well described based on Richards equation (i.e. Buckingham-Darcy-law). The scope of our
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pore scale simulation was to explore in how far a discrete pore scale model can reproduce the observed
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phenomenology at the continuum scale. We came to the following conclusions: • The simulation of infiltration into a 3D pore network by recalculating the entire pressure field after each event of filling single pores leads to infiltration dynamics which are consistent with the classical
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continuum scale approach based on Richards equation.
• The assumption of immiscible and incompressible fluids leads to unrealistic high volumes of en-
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trapped air during infiltration. In reality there are processes as dissolution of the gas phase and the
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formation of bubbles to overcome pore blockage by water menisci. It is not obvious how to represent 21
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such process in a physical consistent way within the simplified geometry of a network model. This is
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expected to be also true for non-cylindrical cross sections of the pores allowing for corner flow.
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6. Acknowledgment We thank DFG for funding within the priority program SPP 1315 and Olaf Ippisch, Kurt Roth for valu-
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References
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[1] I. Fatt, The network model of porous media. I. Capillary pressure characteristics, Trans. AIME 207 (1956) 144–159.
[2] I. Fatt, The network model of porous media. II. Dynamic properties of a single size tube network, Trans. AIME 207 (1956) 160–163.
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able support. We are grateful for the assistance of our colleagues Ji-Youn Arns and Samuel Kwame Kumahor.
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[3] I. Fatt, The network model of porous media. III. Dynamic properties of networks with tube radius distribution, Trans. AIME 207 (1956) 164–181.
[4] V. Joekar-Niasar, S. M. Hassanizadeh, Analysis of fundamentals of two-phase flow in porous media
297
using dynamic pore-network models: A review, Critical Reviews in Environmental Science and Tech-
298
nology 42 (18) (2012) 1895–1976.
300
[5] G. N. Constantinides, A. C. Payatakes, Network Simulation of Steady-State Two-Phase Flow in Consolidated Porous Media, AIChE Journal 42 (1996) 369–382.
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[6] B. Ahrenholz, J. T¨olke, P. Lehmann, A. Peters, A. Kaestner, M. Krafczyk, W. Durner, Prediction of
302
capillary hysteresis in a porous material using lattice-Boltzmann methods and comparison to exper-
303
imental data and a morphological pore network model, Advances in Water Resources 31 (9) (2008)
304
1151–1173.
306
307
saturation-interfacial area relationship for porous media, Adv. Water Resour. 32 (2009) 1632–1640.
[8] X. Yang, C. Liu, J. Shang, Y. Fang, V. L. Bailey, A unified multiscale model for pore-scaleflow simulations in soils, Soil Science Society of America Journal 78 (1) (2014) 108–118.
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[7] M. Porter, M. G. Schaap, D. Wildenschild, Lattice-Boltzmann simulations of the capillary pressure-
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301
309 310
[9] K. Mogensen, E. H. Stenby, A Dynamic Two-Phase Pore-Scale Model of Imbibition, Transport in Porous Media 32 (1998) 299–237.
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[10] K. Mogensen, E. Stenby, S. Banerjee, V. A. Barker, Comparison of Iterative Methods for Computing
312
the Pressure Field in a Dynamic Network Model, Transport in Porous Media 37 (1999) 277–301. 22
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315 316
317 318
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[11] G. Tørå, P.-E. Øren, A. Hansen, A Dynamic Network Model for Two-Phase Flow in Porous Media, Transport in Porous Media 92 (2012) 145–164. [12] H.-J. Vogel, K. Roth, Quantitative morphology and network representation of soil pore structure, Advances in Water Resources 24 (2001) 233–242. [13] A. Raoof, S. M. Hassanizadeh, A New Method for Generating Pore-Network Models of Porous Media, Transport in Porous Media 81 (2010) 391–407, doi:10.1007/s11242-009-9412-3.
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[14] A. Raoof, S. M. Hassanizadeh, A new formulation for pore-network modeling of two-phase flow, Water Resources Research 48 (2012) 1, doi:10.1029/2010WR010180.
[15] H.-J. Vogel, A numerical experiment on pore size, pore connectivity, water retention, permeability, and solute transport using network models, European Journal of Soil Science 51 (2000) 99–105.
[16] W. H. Press, S. A. Saul A. Teukolsky, W. T. Vetterling, B. P. Flannery, Numerical Recipes in C, The Art
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of Scientific Computing, chap. Solution of Linear Algebraic Equations, Cambridge University Press,
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second edn., 83–89, 1992.
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328 329
[17] M. T. van Genuchten, A closed-form equation for predicting the hydraulic conductivity of unsaturated soils, Soil Sci. Soc. Am. J. 44 (1980) 892–898.
[18] W. Durner, Hydraulic conductivity estimation for soils with heterogeneous pore structure, Water Resour. Res. 30 (1994) 211–223, doi:10.1029/93WR02676.
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[19] O. Ippisch, H.-J. Vogel, P. Bastian, Validity limits for the van Genuchten-Mualem model and impli-
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cations for parameter estimation and numerical simulation, Adv. Water Resour. 29 (2006) 1780–1789,
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doi:10.1016/j.advwatres.2005.12.011.
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From pore scale to continuum scale modeling of infiltration J. Tzavaras, M. Kohne, H.-J. Vogel ¨ PII: DOI: Reference:
S0309-1708(16)30281-0 10.1016/j.advwatres.2017.03.005 ADWR 2795
To appear in:
Advances in Water Resources
Received date: Revised date: Accepted date:
23 July 2016 15 November 2016 7 March 2017
Please cite this article as: J. Tzavaras, M. Kohne, H.-J. Vogel, From pore scale to continuum scale ¨ modeling of infiltration, Advances in Water Resources (2017), doi: 10.1016/j.advwatres.2017.03.005
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Highlights • pore network model based on cylindrical pores and nodes without spatial extent • implementation of an infiltration process
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• comparison to Richards equation (continuum scale modeling)
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• biconjugate gradient method with pressure field iterations
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From pore scale to continuum scale modeling of infiltration J. Tzavarasa,∗, M. K¨ohnea , H.-J. Vogela Centre for Environmental Research, Theodor-Lieser-Str. 4, 06120 Halle (Saale), Germany
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Abstract
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Water infiltration in soil at the continuum scale is typically modeled using Richards equation. This requires effective material properties, the water retention characteristic and the unsaturated hydraulic conductivity function. During infiltration the gaseous phase is replaced by water within a complex porous structure. This produces phenomena such as irregular infiltration fronts, hydraulic non-equilibrium and hysteresis which are ultimately related to pore scale processes. In this work we simulate infiltration at the pore scale using a pore network model where the pore structure can be adapted to real structures in terms of pore size distribution and pore topology. We compare the horizontally averaged dynamics of water content and water potential to the results obtained from Richards’ equation. This provides evidence that the pore network representation is consistent with the typical macroscopic dynamics at the continuum scale. However, assuming immiscible and incompressible fluid phases leads to unrealistic gas entrapment in the network model. We conclude that mechanisms leading to a release of trapped gas phase in natural porous media are difficult to represent in a pore network model. Yet, the proposed pore scale approach has the potential to study fundamental relations between pore structure and macroscopic phenomena not only for drainage but also for infiltration.
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1. Introduction
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Keywords: pore network model, pore scale modeling, continuum scale modeling, infiltration, Richards equation
Pore network models (PNMs) have long been used to describe water dynamics in porous media. Based
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Joekar-Niasar and Hassanizadeh [4]. Two-phase flow in a steady state regime was simulated by Constan-
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tinides and Payatakes [5] to predict the macroscopic relative permeabilities, and to relate relative permeabil-
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on the pioneering work of Fatt [1, 2, 3] there is an enormous body of literature mostly dealing with drainage processes (i.e. non-wetting phase replacing wetting phase) and stationary flow. A recent review is given by
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ities to the flow mechanisms at pore level. Wetting process are much more difficult to describe, since the
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dynamics of any individual interface need to be modeled. This can be done by pore scale simulations based
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on Stokes or Navier-Stokes equation to be solved numerically based on Lattice Boltzmann (Ahrenholz et al.
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[6], Porter et al. [7]) or similar approaches. The major drawback is that the pore space need to be explic-
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itly represented within a very limited volume and at a limited resolution. This is why the approach based ∗ Corresponding
author Email addresses: [email protected] (J. Tzavaras), [email protected] (M. K¨ohne), [email protected] (H.-J. Vogel)
Preprint submitted to Elsevier
July 2016
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on Navier-Stokes equation is typically applied to mono-scale porous media as sand or sandstone where the
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relevant pore structure can be captured within a few cubic millimeters. To overcome this problem, Yang
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et al. [8] added a Darcy-term to represent flow in the porous matrix. In this way, smaller pores that are not
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wetting process is difficult to compute. Wetting processes, especially infiltration into relatively dry soil leads
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to macroscopic phenomena as hydraulic non-equilibrium or hysteresis which are relevant for the redistribu-
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tion of precipitation water in soil and which are deemed to be explained by effects of heterogeneities at the
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pore scale. In petroleum engineering this is a highly relevant problem for replacing oil by water.
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explicitly represented for solving Navier-Stokes equation could be represented. A pore network model as used in our study offers the possibility to represent more complex structures as typical for soils, however the
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In contrast to static drainage processes, the simulation of infiltration into network models is challenging
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since the pressure distribution has to be recalculated after each change in fluid saturation to correctly repre-
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sent the final fluid configuration at equilibrium. Solution to this problem has been provided by Mogensen
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and Stenby [9] and was more thoroughly described and elaborated in Mogensen et al. [10] who introduced
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an iterative method to recalculate the pressure field after each time step of infiltration. More recently another
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approach was presented by Tørå et al. [11] who expanded the solution for two-phase flow in a pore network
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model to imbibition, drainage and steady state displacement.
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In our paper we apply the concept of Mogensen et al. [10] to water infiltration in soil. Our pore network
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model (PNM) is based on straight cylindrical pores connected to nodes without spatial extent. The main
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motivation is to explore if the pore scale description is consistent with continuum scale models in terms of
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the macroscopic dynamics of hydraulic state variables, i.e. water content and water potential.
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2. Pore scale modeling
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2.1. Network generation
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To generate a realistic pore network model (PNM) we use the concept introduced by Vogel and Roth
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[12]. Thereby, relevant structural properties as pore size distribution and pore topology can be preserved
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while less relevant details such as surface roughness are simplified. The PNM is based on a face-centered
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cubic grid (coordination number 12) with cylindrical bonds representing pores while the nodes have zero
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volume. Pore size distribution and pore topology are adjusted to measured values as obtained from 3D
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CT images. To represent the measured pore geometry only a small part of the 12 possible bonds per node
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are required so that the effective coordination number Zeff is smaller than Zmax = 12. In contrast to other
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approaches where bonds are removed by some random or regular process (Raoof and Hassanizadeh [13])
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we build up the network starting from the largest pores so that the Euler number of each pore size class as
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measured in the CT images is reproduced. A special feature of our network model is that the remaining
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bonds (i.e. Zmax − Zeff ) are considered as “background porosity”. This accounts for the fact that in soil
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there are always small pores that are not resolved by the imaging technique (CT). The resolution of CT
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images is at best 0.01 mm while clay particles in soil are much smaller. As a consequence, these small pores
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cannot be represented in the network of discrete pores, however, they definitely contribute to water flow. 2
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pore diameter EPC (str.) EPC (ran.)
0.04 -34.49 -45.37
0.066 -1.92 -5.61
0.092 -0.01 1.57
0.118 0.47 3.69
0.144 0.37 2.65
0.169 0.39 1.66
0.207 0.27 1.05
0.253 0.24 0.88
0.299 0.15 0.67
0.345 0.08 0.54
Table 1: Pore diameter and measured Euler Numbers for the structured and random PNM.
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With adding this background porosity described by some mean pore size smaller than the other pores in the PNM, this effect is accounted for. In this way also the water phase is always continuous reflecting the natural
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situation of moist soil. In other PNMs this important feature is obtained by using angular pores (Raoof and
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Hassanizadeh [14], Joekar-Niasar and Hassanizadeh [4]). The background porosity was assigned a small
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pore diameter dmin = 0.007 mm. This value is considerably smaller than the pores resolved by CT (0.04
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mm) and was chosen such that the unsaturated conductivity attains realistic values.
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The pore size distribution and the pore topology was adapted to a loess soil which has already been studied by Vogel [15]. We generate a ’structured PNM’ taking account of the measured topology and a ’random PNM’ where the same pores with the same size distribution are connected randomly. The structured
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and the random grid both have a size of 16 × 16 × 32 nodes. These dimensions are large enough so that the
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simulations converged to stable results while they are yet small enough to be numerically tractable. The pore
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size distribution is represented by ten discrete pore size classes. In Table 1 the pore diameters and measured
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Euler Numbers for the two different PNMs are listed. The definition of the specific Euler number χV referred
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to as EPC in Table 1 is given by:
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N +C −H (1) V It is based on the fundamental topological properties of a volume V, which are the number of isolated
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objects N, the number of redundant connections or loops C often referred to as connectivity or genus and the
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number of completely enclosed cavities H corresponding to hollow spheres (for more details see Vogel and
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Roth [12]).
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χV =
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(results not shown). This corroborates the well known fact that pore topology is critical for infiltration. We
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doubled the coordination number from 2.5 (structured PNM) to 5.0 for the random PNM to increase the pore
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connectivity for the random PNM. As a consequence, the grid constant (i.e. the distance between adjacent
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nodes) was increased from 0.258 mm (structured PNM) to 0.364 mm and the vertical height of the network
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from 5.66 mm to 7.98 mm to represent the same porosity for the given number of nodes.
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When using the same pore size distribution and the same coordination number as for the structured PNM, first simulations indicated that infiltration into the random PNM was blocked due to entrapped gas phase
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2.2. Calculation of flow To calculate water flow within the pore network as a consequence of some external gradient in water
pressure pw we use Kirchhoffs’ law to guarantee the required mass balance at each node i:
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qi j = 0
(2)
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where qi j is the volumetric flow in the pore connecting the nodes i and j, in the following referred to as pore i j. The pressure in the water phase pw is related to the capillary potential pc as follows: pc = pw − pa
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defined as the sum of capillary potential pc and gravitational potential pg :
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(3)
The driving force for vertical infiltration into the porous network is the total hydraulic potential ψw
ψw = pc + pg 81
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(4)
(5)
with ρw [ML−3 ] the density of water, g [LT −2 ] the gravitational acceleration and h [L] the height above the lower boundary of the network.
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During transient conditions we need to distinguish three different configurations of phase distribution within an individual pore to calculate qi j : i) completely water saturated, ii) completely gas saturated or iii)
87
partially filled with both phases (i.e. the pore is in the state of infiltration).
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For water-filled pores (see Fig. 1a)) the flow is obtained by:
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qi j = Gi j (ψw,i − ψw, j ),
where the hydraulic conductivity Gi j is given by:
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(6)
Gi j =
πri4j 8η
(7)
with ri j the radius of the pore i j and η the viscosity. We assume complete wettability of the solid surfaces.
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During infiltration gas-filled pores are gradually invaded by water. Water can invade a pore with radius ri j from node i (see Fig. 1b)) if and only if all of the following requirements are met:
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ρw gλi j 1. pc,i + α √ > − 2σ ri j 2 2. There is no water entering from the opposite side of the pore.
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3. There is a continuous air path from the neighboring node j to the upper or lower boundary of the model.
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4. No water has entered the pore and ψw,i ≥ ψw, j or the pore is already partly filled.
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As described in condition 1, the capillary pressure at node i needs to exceed the entry pressure of a given pore described by the Young-Laplace equation. Once the pore is already partially water-filled with a length λi j [L] an additional gravitational component for the water column inside the pore needs to be considered. The weight factor α accounts for the direction of filling, α = {1, 0, −1} for downward, horizontal or upward flow respectively.
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During infiltration of a pore the local flow is described by:
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! ρw gλi j 2σ qi j = Gmin (ψw,i − ψw, j ) + Gi j pc,i + α √ + (8) ri j 2 The first term represents water flow along the walls of gas-filled pores. The corresponding conductivity
106
Gmin is set to the same value as the background porosity. Such a wall flow is a reasonable assumption
107
and, moreover, it renders the numerical calculation of the pressure field more stable. For the second term
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describing the pore filling only the capillary potential and not the total hydraulic potential is taken into
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account because the driving force of the filling process is independent from the gravitational potential at
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node i. The condition under which a pore is to be filled is the same for all the pores irrespective of their
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height.
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For gas-filled and partially filled pores in which bulk flow is not taking place and for ’background porosity’ (see Fig. 1c)) we assume a small water-filled radius rmin so that
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qi j = Gmin (ψw,i − ψw, j )
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with
Gmin =
4 πrmin 8η
(10)
After infiltration of a given pore, the continuity of the air phase to the lower and upper boundary is
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(9)
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updated for each node in the network so that condition 3 can be easily checked in the following time steps.
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2.3. Initial and boundary conditions Initially the capillary potential is set to a fixed value within the entire network which mimics stationary
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gravity flow at this potential. The initial water saturation corresponds to the volume of pores that are water
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filled at this potential. To simulate infiltration we impose a higher but fixed capillary potential at the inlet
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nodes of the upper boundary. At the lower boundary a gravitational pressure gradient is applied. This is es-
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tablished by setting the capillary potential at the nodes of the lower boundary equal to the values of the nodes
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in the second lowest layer. However, this procedure leads to artifacts in case that the hydraulic conductivity
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of the lower layer (i.e. the bonds between the lowest and the second lowest nodes) is higher compared to
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the layer above. In this case, the reduced water potential in the second lowest level, which was set equal to
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the lowest level, induces a feedback so that gravity flow conditions (i.e. a constant matric potential along the
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vertical axis) are not reached. We solved this problem by changing the pore size distribution of the lower
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level such that it is smaller than that of the layer above. In this way, the artificial impact of the lower bound-
130
ary on the dynamics within the network is minimized to become negligible. The lateral faces are periodic in the horizontal plane to prevent undesired boundary effects.
a)
b)
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Figure 1: Rule based filling mechanisms: a) example for mechanism of water filled pores with bulk flow possible b) example for mechanism of the gradually filling of a gas-filled pore c) examples for mechanism of gas-filled and partly filled pores in which bulk flow is not possible and there exist only flow along the ’background porosity’. Left: pressure level at node i insufficient to fill adjacent bigger pores, right: no bulk flow in pore i j due to entrapped air 131
2.4. Dynamics of infiltration
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Infiltration was initiated by setting the matric potential at the uppermost nodes, pc,inlet to some value
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above the current state of the network. In a first step all bonds connected to the upper boundary nodes where
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ri, j ≥ 2σ/pc,inlet are filled with water. In the following, the dynamics of moving water/air interfaces were 6
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calculated by updating the pressure field and then using the rule based filling conditions after each time-step
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to calculate fluxes and update water saturation at each pore. The dynamic time-steps are defined by the
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actual time required to fill the next pore completely. This time-step is calculated with respect to all pores i j
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containing a moving interface: (
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For the entire network the flow balance system can be formulated in matrix notation as: A(p)p = b(p)
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(11)
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) Va,i j tmin = min qi j Here Va,i j is the air-filled volume of a pore i j and qi j is the flow of the wetting phase into it.
(12)
where A(p) is the n × n matrix containing the conductivities between n individual nodes Gi j and Gmin .
Note that air-filled pores have a low fixed conductivity Gmin . The vector p contains the unknown pressures
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at the nodes, b is the vector containing the given pressures at the upper and lower boundaries pinlet and poutlet
144
multiplied by the conductances of the bonds connected to these boundaries and the capillary pressures and
145
conductances of pores being filled. A biconjugate gradient method was used to solve the resulting system of
146
linear equations ( Press et al. [16] ). Following the suggestion of Mogensen et al. [10] the calculation of the
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pressure field was done iteratively by minimizing the function
1 T p Ap − b(p)T p (13) 2 for each time-step. Since f (p) opens upwards and is convex it has an extremum for exactly one vector p
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f (p) =
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which is the global minimum of f (p). This is obtained based on an iterative approach of the form
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A(pk )pk+1 = b(pk ), k = 0, 1, ...
(14)
When the initial vector p0 is chosen to match the pressure solution of the previous time-step, the number of steps required to minimize f (p) was found to be very small. Solving the linear system of equations a stable and fast solver is necessary. In contrast to the method
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suggested by Mogensen and Stenby [9] (conjugate gradient method preconditioned by symmetric succes-
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sive overrelaxation) we used the so called biconjugate gradient method. A mathematical description of the
155
method as well as the computer code of the solver is provided by Press et al. [16]. A set of solvers belonging
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to the ITPack software package (FORTRAN code - i.e. Jacobi Conjugate Gradient (JCG), Sucessive Over-
157
relaxation (SOR), Symmetric SOR Conjugate Gradient (SSORCG), Reduced System Semi-Iteration (RSSI)
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solver) was also tested and gave very similar results.
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3. Continuum scale modeling
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To model infiltration at the continuum scale we used the classical Richards equation in its one-dimensional
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∂t θ(h) − ∂z K(h)[∂z (h + z)] = 0 162
(15)
where z denotes the vertical coordinate pointing upwards. This equation relies on two hydraulic material
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properties, the water retention curve θ(h) and the unsaturated hydraulic conductivity function K(h). The
164
volumetric water content is given by θ [-], K [LT−1 ] denotes the hydraulic conductivity and h [L] is the soil
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matric potential in the form of hydraulic head. The latter is related to capillary pressure by pc = ρw gh. To allow for a direct and consistent comparison between pore scale and the continuum scale simulations
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we obtained both hydraulic functions from simulations of the PNM. This was done for a stepwise wetting
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of the PNM to describe the imbibition branch of the hysteretic functions. According to the ten pore size
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classes of the PNM, this led to 10 discrete points for both functions. For a parametric description of θ(h) we
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fitted a van Genuchten model (van Genuchten [17]) in its bimodal form according to Durner [18] to increase
171
flexibility. For the hydraulic conductivity function we fitted a spline to the data points. Note that for the
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scope of this paper it is important to get a good description of the data points simulated by PNM while the
173
number of parameters to do so is not critical.
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Finally, based on the parameterized hydraulic functions, Richards equation was solved for the same
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pressure steps as for the PNM using the software package µPhi (Ippisch et al. [19]). This code uses a cell-
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centered finite volume scheme for spatial discretization and the solver is based on an implicit Euler scheme
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in time and a full upwind scheme in space while the time step is adapted automatically.
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4. Results and discussion
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4.1. Effective properties
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For both the structured and random PNM we simulated infiltration in 10 pressure steps. After each step
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we waited for the system to reach hydrodynamic equilibrium (i.e. no changes in local pressures anymore)
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before initiating the next increase in pressure. We started from a drained model with a pressure of -74 hPa
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throughout the model slightly lower than the capillary pressure of the smallest measured pore size class.
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The drainage function which was used to drain the model, was already tested and validated (Vogel and Roth
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[12]). The first infiltration cycle was simulated by setting the pressures at the top plane of the model (upper
186
boundary) to a pressure of -44 hPa slightly higher than the capillary pressure of the second smallest pore
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size. During the second step the pressure at the upper boundary was raised to a level of -31 hPa a little bit
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higher than the capillary pressure of the third smallest pore size and so on.
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Combined plots for the simulated hydraulic functions of the structured grid in contrast to the random
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grid are shown in Figs. 2 and 3. The first plot for both models contains the data points of the water content
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over the pressure head obtained by the PNM together with the water retention curve (i.e. capillary pressure saturation relation) as obtained after fitting the van Genuchten parameters of a bimodal model to the output
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data of the PNM. The fitting function of the bimodal model reads:
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Sw =
X
ωi (1 + (αi pc )ni )−(1+1/ni )
(16)
i
Sw = and
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X
θ − θr θ s − θr
(17)
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ωi = 1
(18)
i
with S w : water saturation, θ s : water content at saturation, θr : residual water content, α1 , α2 , n1 ,n2 : van
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Genuchten paramters for submaterial 1 and 2, ω: fraction of the submaterial 1 of the total material.
In the second plot the fitted spline interpolation is shown together with the simulated data point for
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hydraulic conductivity. We observe significantly higher hydraulic conductivity values for the random PNM. 0.36 0.355 0.35
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structured PNM: datapoints fit random PNM: datapoints fit
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Figure 2: Water retention characteristics simulated by the network Model (symbols) and fitted parameterization (lines) for the structured (blue) and the random PNM (red). The porosity in both networks was fixed to 0.5027
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structured PNM: datapoints fit random PNM: datapoints fit
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Figure 3: Hydraulic conductivities simulated by the network Model (symbols) and spline interpolation (lines) for the structured (blue) and the random PNM (red).
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There is a considerable difference in hydraulic properties between the random and the structure PNM although the pore size distributions are identical. This is explained by the different topology of the models
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leading to a different amount of entrapped air within the various pore size classes. This is illustrated in Fig. 4.
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In the structured grid much more air is entrapped in small pores (water filled at pc < 31 hPa) but less in the
204
larger pores. This is due to the connectivity of the pores as indicated by the Euler numbers (Tab. 1) with
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lower values for higher connectivity. The connectivity of small pores in the random PNM is increased due
206
to the increased coordination number as explained above while the connectivity of larger pores is slightly
207
increased in the structured PNM reflecting the connectivity of the natural pore space. This explains the
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different shape of the water retention characteristics.
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The assumption of immiscible fluids leads to a large volume of air entrapments (80-90%) in the larger
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pores (water filled above pc ≥ 31 hPa). Thus, hydraulic conductivity is mainly governed by the two smaller
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pore size classes which are better connected with an increased water saturation within the random PNM. This is why the random PNM exhibits considerably higher conductivities.
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We are aware that the enormous volume of air entrapment is not quite realistic for the original soil
214
where pore size and topology was measured. This is rather a consequence of assuming incompressible and
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immiscible fluids and no additional processes such as dissolution of the gas phase and leaking of bubbles
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due to local pressure gradients allowing for fluids to escape once they are trapped. However for the scope of
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this work this is not critical.
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Figure 4: Entrapped air at different capillary potentials. 218
4.2. Infiltration into the pore network models
To compare the results of pore scale with continuum scale infiltration we simulated infiltration into the
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two smallest pore size classes of the PNM. Most of the water infiltrates at these pressure steps due to air
221
entrapments in the larger pore size classes. The infiltration process into the entire network from top to the
222
bottom is illustrated in Figs. 5 and 6. Qualitatively this confirms the validity of the rule based pore filling
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procedure. The infiltration front in the random PNM is remarkably sharper as compared to the structured
224
grid. The reason for this is a more uniform velocity profile due to the random distribution of pores at higher
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coordination number in contrast to the more clustered topology of the structured PNM.
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For a reliable interpretation of the results it is crucial that the PNMs are large enough to actually reflect
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Figure 5: The invasive infiltration process with increasing time (left to right) for the structured grid. First pressure step allowing the two smallest pore size classes to be filled consecutively from top to bottom. Air: red, water: blue.
Figure 6: The same illustration as in previous figure for the random grid.
In Fig. 7 pressure profiles during infiltration are shown. The pressure was calculated as an average over
229
all nodes within a horizontal plane. The curves are smoother as compared to random PNM (shown in Fig. 8)
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which is due to the sharper infiltration front in the random PNM. Both models converge toward gravity flow
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and dynamic equilibrium at the end of the infiltration process.
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t=0s t=0.1s t=0.2s t=0.3s t=0.4s t=0.5s t=0.6s t=0.7s t=0.8s t=0.9s t=1.0s t=1.2s t=1.4s t=1.6s t=1.8s t=2.0s t=2.5s t=3.0s t=3.5s t=4.0s t=5.0s t=6.0s t=7.0s t=8.0s t=10s t=20s t=30s t=600s t=4000s
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Figure 7: Pressure profile for the structured grid. The two vertical red lines indicate the capillary pressure of the smallest (d = 0.04mm) and second smallest (d = 0.066mm) pore sizes, at which the pores of these sizes can be filled.
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t=0s t=0.1s t=0.2s t=0.3s t=0.4s t=0.5s t=0.6s t=0.7s t=0.8s t=0.9s t=1.0s t=1.2s t=1.4s t=1.6s t=1.8s t=2.0s t=2.5s t=3.0s t=3.5s t=4.0s t=4.5s t=5.0s t=7.0s t=122s
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Figure 8: The same plot as in previous figure for the random grid.
For a reliable interpretation of the results it is crucial that the PNMs are large enough so that the observed
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behavior can actually be related to the pore scale attributes (i.e. pore size distribution and topology). To
234
demonstrate in how far this can be done, we simulated 5 different realizations for both, the structured and
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the random network. The small standard deviation of the pressure profiles of the different realizations clearly suggests that the volume of the networks is large enough to draw some general conclusions (see Fig. 9).
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t=0s treal. 1=0.1s treal. 2=0.1s treal. 3=0.1s treal. 4=0.1s treal. 5=0.1s treal. 1=1.0s treal. 2=1.0s treal. 3=1.0s treal. 4=1.0s treal. 5=1.0s treal. 1=2.0s treal. 2=2.0s treal. 3=2.0s treal. 4=2.0s treal. 5=2.0s
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t=0s treal. 1=0.1s treal. 2=0.1s treal. 3=0.1s treal. 4=0.1s treal. 5=0.1s treal. 1=1.0s treal. 2=1.0s treal. 3=1.0s treal. 4=1.0s treal. 5=1.0s treal. 1=2.0s treal. 2=2.0s treal. 3=2.0s treal. 4=2.0s treal. 5=2.0s
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Figure 9: Comparisons of the pressure profiles of 5 realizations of the structured (above) and random (below) grid plotted for three different times.
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The dynamics of the water content during the same infiltration process is shown in Figs. 10 and 11. It
238
was calculated as an average over the bonds connected to all nodes within a horizontal plane. As for the
239
pressure the water front infiltrates from top toward the bottom. However, the water content profiles show two
241
subsequent waves. First, the smaller pore size class is infiltrated and only when these pores are filled within the entire network the larger pore size class starts to be invaded from the top. This is due to the discrete
240
pore size classes having a fixed pore size each. At the bottom, the water content within the lowest layer is increased because the mean pore size in this layer was reduced to avoid boundary effects as explained in
244
section 2.3..
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245
The infiltration dynamics is similar for the structured and the random PNM while the absolute water con-
246
tent in the random PNM is somewhat higher because of the increased coordination number of this network.
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Figure 10: Water content profile for the structured grid.
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t=0s t=0.1s t=0.2s t=0.3s t=0.4s t=0.5s t=0.6s t=0.7s t=0.8s t=0.9s t=1.0s t=1.2s t=1.4s t=1.6s t=1.8s t=2.0s t=2.5s t=3.0s t=3.5s t=4.0s t=5.0s t=6.0s t=7.0s t=8.0s t=10s t=20s t=30s t=600s t=4000s
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Figure 11: Water content profile for the random grid.
4.3. Comparison with the continuum model
Starting from the same initial conditions, the same pressure steps as applied for the PNM simulation
249
were implemented as boundary conditions for 1D Richards equation. We used the water retention curve and
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the hydraulic conductivity function as shown in Figs. 2 and 3, respectively. To compare the results of the 3D PNM model with those of 1D Richards equation we averaged the water
252
potential and the water content in each horizontal layer of the PNM. The results for the structured grid are
253
shown in Fig. 12. Overall the infiltration profiles are similar, however, there are mainly two remarkable
254
differences. First, the infiltration front within the PNM model is sharper and second, the propagation of the
255
pressure front is initially slower in the PNM and accelerates after the tip of the front reached the bottom.
256
In contrast, the results of Richards equation are more gradual and smoother in space and time. The random
257
PNM (Fig. 13) shows the same behavior but even more pronounced. This is explained by the two discrete
258
pore size classes that are invaded in the PNMs. Each pore size class has a fixed pore diameter so that the
259
critical pressure to infiltrate the larger pores is only reached after the smaller pores were saturated.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 6s PNM t = 6s Muphi t = 7s PNM t = 7s Muphi t = 8s PNM t = 8s Muphi t = 10s PNM t = 10s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 600s PNM t = 600s Muphi t = 4000s PNM t = 4000s Muphi
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Figure 12: Pressure profile comparison with Richards equation for the structured grid.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 7s PNM t = 7s Muphi t = 122s PNM t = 122s Muphi
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Figure 13: Pressure profile comparison with Richards equation for the random grid.
Comparing the water content profiles in Figs. 14 and 15 clearly demonstrates the consecutive infiltration
261
into the two different pore size classes. Individual pores can only be filled in the PNM if the matric potential
262
at the node reaches the capillary pressure of these pores. Obviously this critical capillary pressure is only
263
reached for the larger pore size class when the smaller pores are already infiltrated at the bottom. This
264
leads to the observed stepwise increase in water content and a sharper invasive infiltration front as already
265
discussed for the pressure profiles. Since the water retention characteristic used for the continuum scale
266
model was obtained from PNM-simulations the water content averaged over the entire domain agrees well
267
for the two model concepts. Due to the local heterogeneity within different horizontal planes of the PNM
268
the water content profiles observed in the PNM are less smooth.
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t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 6s PNM t = 6s Muphi t = 7s PNM t = 7s Muphi t = 8s PNM t = 8s Muphi t = 10s PNM t = 10s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 600s PNM t = 600s Muphi t = 4000s PNM t = 4000s Muphi
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Figure 14: Water content profile comparison with Richards equation for the structured grid.
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depth z in mm
-2
t = 0s t = 1s PNM t = 1s Muphi t = 2s PNM t = 2s Muphi t = 3s PNM t = 3s Muphi t = 4s PNM t = 4s Muphi t = 5s PNM t = 5s Muphi t = 7s PNM t = 7s Muphi t = 10s PNM t = 10s Muphi t = 15s PNM t = 15s Muphi t = 20s PNM t = 20s Muphi t = 30s PNM t = 30s Muphi t = 50s PNM t = 50s Muphi t = 80s PNM t = 80s Muphi t = 122s PNM t = 122s Muphi
-4 -5
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0.325
0.33
0.335 0.34 water content [-]
0.345
0.35
0.355
5. Conclusions
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Figure 15: Water content profile comparison with Richards equation for the random grid.
We simulated water infiltration into a 3-dimensional pore network model representing the statistical
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properties of the pore size distribution and the pore connectivity of an undisturbed soil. We compared the
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obtained dynamics of capillary potential and water content to the results of a 1D continuum scale model
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based on Richards equation. For macroscopically homogeneous media the phenomenology of water dy-
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namics can be well described based on Richards equation (i.e. Buckingham-Darcy-law). The scope of our
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pore scale simulation was to explore in how far a discrete pore scale model can reproduce the observed
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phenomenology at the continuum scale. We came to the following conclusions: • The simulation of infiltration into a 3D pore network by recalculating the entire pressure field after each event of filling single pores leads to infiltration dynamics which are consistent with the classical
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continuum scale approach based on Richards equation.
• The assumption of immiscible and incompressible fluids leads to unrealistic high volumes of en-
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trapped air during infiltration. In reality there are processes as dissolution of the gas phase and the
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formation of bubbles to overcome pore blockage by water menisci. It is not obvious how to represent 21
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such process in a physical consistent way within the simplified geometry of a network model. This is
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expected to be also true for non-cylindrical cross sections of the pores allowing for corner flow.
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6. Acknowledgment We thank DFG for funding within the priority program SPP 1315 and Olaf Ippisch, Kurt Roth for valu-
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References
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[1] I. Fatt, The network model of porous media. I. Capillary pressure characteristics, Trans. AIME 207 (1956) 144–159.
[2] I. Fatt, The network model of porous media. II. Dynamic properties of a single size tube network, Trans. AIME 207 (1956) 160–163.
AN US
290
CR IP T
288
able support. We are grateful for the assistance of our colleagues Ji-Youn Arns and Samuel Kwame Kumahor.
287
[3] I. Fatt, The network model of porous media. III. Dynamic properties of networks with tube radius distribution, Trans. AIME 207 (1956) 164–181.
[4] V. Joekar-Niasar, S. M. Hassanizadeh, Analysis of fundamentals of two-phase flow in porous media
297
using dynamic pore-network models: A review, Critical Reviews in Environmental Science and Tech-
298
nology 42 (18) (2012) 1895–1976.
300
[5] G. N. Constantinides, A. C. Payatakes, Network Simulation of Steady-State Two-Phase Flow in Consolidated Porous Media, AIChE Journal 42 (1996) 369–382.
ED
299
M
296
[6] B. Ahrenholz, J. T¨olke, P. Lehmann, A. Peters, A. Kaestner, M. Krafczyk, W. Durner, Prediction of
302
capillary hysteresis in a porous material using lattice-Boltzmann methods and comparison to exper-
303
imental data and a morphological pore network model, Advances in Water Resources 31 (9) (2008)
304
1151–1173.
306
307
saturation-interfacial area relationship for porous media, Adv. Water Resour. 32 (2009) 1632–1640.
[8] X. Yang, C. Liu, J. Shang, Y. Fang, V. L. Bailey, A unified multiscale model for pore-scaleflow simulations in soils, Soil Science Society of America Journal 78 (1) (2014) 108–118.
AC
308
[7] M. Porter, M. G. Schaap, D. Wildenschild, Lattice-Boltzmann simulations of the capillary pressure-
CE
305
PT
301
309 310
[9] K. Mogensen, E. H. Stenby, A Dynamic Two-Phase Pore-Scale Model of Imbibition, Transport in Porous Media 32 (1998) 299–237.
311
[10] K. Mogensen, E. Stenby, S. Banerjee, V. A. Barker, Comparison of Iterative Methods for Computing
312
the Pressure Field in a Dynamic Network Model, Transport in Porous Media 37 (1999) 277–301. 22
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314
315 316
317 318
319 320
321 322
[11] G. Tørå, P.-E. Øren, A. Hansen, A Dynamic Network Model for Two-Phase Flow in Porous Media, Transport in Porous Media 92 (2012) 145–164. [12] H.-J. Vogel, K. Roth, Quantitative morphology and network representation of soil pore structure, Advances in Water Resources 24 (2001) 233–242. [13] A. Raoof, S. M. Hassanizadeh, A New Method for Generating Pore-Network Models of Porous Media, Transport in Porous Media 81 (2010) 391–407, doi:10.1007/s11242-009-9412-3.
CR IP T
313
[14] A. Raoof, S. M. Hassanizadeh, A new formulation for pore-network modeling of two-phase flow, Water Resources Research 48 (2012) 1, doi:10.1029/2010WR010180.
[15] H.-J. Vogel, A numerical experiment on pore size, pore connectivity, water retention, permeability, and solute transport using network models, European Journal of Soil Science 51 (2000) 99–105.
[16] W. H. Press, S. A. Saul A. Teukolsky, W. T. Vetterling, B. P. Flannery, Numerical Recipes in C, The Art
324
of Scientific Computing, chap. Solution of Linear Algebraic Equations, Cambridge University Press,
325
second edn., 83–89, 1992.
327
328 329
[17] M. T. van Genuchten, A closed-form equation for predicting the hydraulic conductivity of unsaturated soils, Soil Sci. Soc. Am. J. 44 (1980) 892–898.
[18] W. Durner, Hydraulic conductivity estimation for soils with heterogeneous pore structure, Water Resour. Res. 30 (1994) 211–223, doi:10.1029/93WR02676.
M
326
AN US
323
[19] O. Ippisch, H.-J. Vogel, P. Bastian, Validity limits for the van Genuchten-Mualem model and impli-
331
cations for parameter estimation and numerical simulation, Adv. Water Resour. 29 (2006) 1780–1789,
332
doi:10.1016/j.advwatres.2005.12.011.
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CE
PT
ED
330
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