Table of Contents

Cover

Foreword

Introduction

1 Physico-chemistry of the Soil–Water System

1.1. The “abnormal” properties of water
1.2. Properties of the water molecule
1.3. Pure liquid water
1.4. Solutions properties
1.5. Calculation of activity coefficients
1.6. The matric potential
1.7. Osmotic potential and matric potential
1.8. Interaction with solid surfaces
1.9. Soil and microenvironment heterogeneity
1.10. Appendix: conditions for water stability
1.11. Bibliography

2 Soil Wettability

2.1. Introduction
2.2. Substrate wettability
2.3. Diffuse interface
2.4. Wetting dynamics
2.5. Capillarity
2.6. Soil wettability: beyond capillarity
2.7. Conclusion
2.8. Bibliography

3 Water Uptake by Plants

3.1. Introduction
3.2. The cohesion-tension theory
3.3. Soil roles
3.4. Roles of roots
3.5. Soil/roots interactions
3.6. Soil/roots systems biophysical models
3.7. Conclusion
3.8. Appendix: demonstration of Equation [3.4]
3.9. Bibliography

4 Preferential Flows

4.1. Water and solute transport
4.2. Notion of “preferential flow”
4.3. Experimental study
4.4. Originating mechanisms
4.5. Models
4.6. Bibliography

5 Floods

5.1. When society programs disasters
5.2. From empiricism to modeling
5.3. The naturalist alternative
5.4. The alluvial environment, a place for confrontations
5.5. Moving from a defensive–curative to a preventive–innovative approach
5.6. Toward qualitative space management?
5.7. Bibliography

List of Authors

Index

End User License Agreement

List of Illustrations

1 Physico-chemistry of the Soil–Water System

Table 1.1. Coordinates of two triple points and the critical point of water
Table 1.2. Values of the specific volume, the enthalpy and the dielectric constant of water at 0°C, 100°C and 1 bar and at the critical point (see Chaplin, Martin “Water structure and science”, www1.lsbu.ac.uk/water and the several references cited)
Table 1.3. Thermodynamic properties of pure liquid water and OH^– under standard conditions [Bra89]
Table 1.4. Main vibration modes of the isolated water molecule
Table 1.5. Comparison of the components of dispersion forces in argon and water [Ger95, p. 11]. α is the polarizability of the molecule and μ is its electric dipole moment
Table 1.6. Debye–Hückel equations and their validity domains. I is the ionic strength of the solution. The parameters A_γ and B_γ are explicit functions of temperature, density and the dielectric constant of pure water. At 25°C, A_γ = 0.5095, B_γ = 0.3284, the parameter being in Å, and C = 0.041 kg.mol^–1, adjusted to NaCl solutions [Hel69]
Table 1.7. Composition of spring water on granite in Fougères (Armorican Massif)
Table 1.8. Distribution of aqueous species in a spring water on granite in Fougères, calculated by Phreeqc
Table 1.9. Composition of a solution from Chott El Jerid, Tunisia
Table 1.10. Distribution of aqueous species in water from Chott El Jerid, calculated with the Pitzer model
Table 1.11. Saturation indices of some minerals for water from Chott El Jerid
Table 1.12. Relations between water height, pF and water activity and the equivalent diameter of the pores at 25°C

List of Tables

1 Physico-chemistry of the Soil–Water System

Figure 1.1. Water stability domain in the pe and pH diagram at 25°C, 1 bar
Figure 1.2. Structure of the isolated water molecule. The angle is equal to α = 104.52°, and the distance O-H is 0.9572 ± 0.0003Å
Figure 1.3. Diagram of the molecular orbitals of water. At the bottom, the first molecular orbitals 1a₁, 1 b₂ and 2a₁ are bonding orbitals; at the center, the atomic orbital 1 b₁ is non-bonding; on top, the orbitals 2 b₂ and 3 a₁ are antibonding. HOMO, highest occupied molecular orbital; LUMO, lowest unoccupied molecular orbital (source: [Cha16], modified). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 1.4. Tetrahedral model of the water molecule by [BS72]. Oxygen is at the center of a regular tetrahedron, in which two vertices are occupied by the hydrogen atoms, located in the yz plane, and the other two by negative charges, located in the xz plane. The distance O-H is 1Å. The center of mass, the origin of the coordinate system, is slightly below the center of the tetrahedron. Partial charges carried by the vertices are q = ±ηe, where η = 0.2357 and e is the electron charge
Figure 1.5. The first hydration shell of the octahedric Al³⁺ ion, with coordination number 6
Figure 1.6. Forms of positively charged elements in solution in water according to their nominal electric charge Z and their ionic radius R. Ionic radii are calculated for a cation coordinated to six oxygens, except for oxyanions that are coordinated to four oxygens; the values are taken from [WM70]
Figure 1.7. Allred–Rochow electronegativities of the elements
Figure 1.8. Locations of cations according to their nominal charge and free atom electronegativity taken on the Allred–Rochow scale (source: [JHL94], modified). The curves that separate groups I, II, III, IV and V are defined by critical affinity thresholds of the proton for the cation hydration shell or for the solvent [JHL94, p. 233 sqq.]. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip

2 Soil Wettability

Figure 2.1. Different forms of drops according to the substrate. The complete wetting correspond to the maximal spread of the drop. With partial wetting, the drop makes a contact angle α. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.2. Variation of the macroscopic contact angle α_a with respect to the mean area. For a surface presenting angles, on the right-hand side, α_a is comprised between α and α + β
Figure 2.3. Forces resulting from surface tension γ. (a) The mobile bar of length L is subject to the force 2γL. (b) The resultant of tension forces is non-zero if the curvature is not zero; the direction of the resultant (toward the top or the bottom) depends on the sign of the surface curvature. Diagram (b) corresponds to the case of Gerris, which must have enough of a surface in contact with water to ensure that the resultant balances gravity. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.4. Laplace pressure on the surface of a liquid: overpressure p₊ if the surface is convex and depression p_- if the surface is concave
Figure 2.5. Balance of surface tensions at the triple line for a (a) hydrophilic (α < 90°) and (b) hydrophobic substrate (α > 90°). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.6. Different profiles of disjunction pressure, given by equation [2.9], for different values of parameter b. For b, < b_c ≃ 1.56, there exists a height interval for which the disjunction pressure is increasing. This is a repulsive interaction (see section 2.3.2). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.7. Simulation of spinodal dewetting at two different times. The labyrinthine structure has increased in size (simulations from the left hand side to the right hand side) during the slow coalescence phenomenon called coarsening [BT10] (source: © 2010 Society for Industrial and Applied Mathematics; reproduced with authorization; all rights reserved). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.8. Profile of a drop coexisting with a very thin precursor film for the disjoining pressure given by [2.9]
Figure 2.9. Advancing α_a and receding angles α_r of a drop on an inclined plane. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.10. Emergence of streams after a front has passed on a transverse defect. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.11. Diagram of a meniscus on the edge of a wall in partial hydrophilic wetting. The volume Ω in dark blue is the control volume. Horizontal arrows represent pressure forces acting on this surface of Ω. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.12. Diagram of the capillary rise h in a tube of radius r. The proportion between h and r is not respected (h ≫ r) in order to clearly show the meniscus. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.13. Distribution of pore sizes according to soil nature (source: [Daï13]). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.14. Diagram of trapped water in the porous medium: (a) inside the interpores volume; (b) in the form of a precursor film covering the pores and grains. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.15. Diagram of sand becoming hydrophobic due to the presence of a layer of amphiphilic organic matter. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 2.16. Surface flow and formation of preferential flows
Figure 2.17. Spontaneous fingering at the interface between layers of fine grains (90 µm for f₁ and 125 µm for f₂) and coarser grains (500 µm for c₁ and 850 µm for c₂). The diagram is made based on the experiment of infiltration by [ST00]. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip

3 Water Uptake by Plants

Figure 3.1. Soil characteristic water content. θ_h : hygroscopic water content, dry soil in equilibrium with air humidity; θ_fp: permanent wilting point; θ_ft: temporary wilting point; θ_cc: field capacity; θ_s: saturation water content. The water stock between θ_fp and θ_cc on the root depth defines the available water capacity (AWC) separated into a readily available (RAC) and hardly available capacity (HAC) by θ_ft. Gravitational water is the water that can circulate under the action of gravity and which is drained at depth. Unavailable water is water too strongly retained by the soil to be used by the plant
Figure 3.2. Profiles of water content measured in the vicinity of a single radish root over time.
Figure 3.3. Simulation of the effect of the spatial distribution of roots in soil on water uptake. A. Three types of horizontal spatial distribution of roots (which can be measured in the field by excavating the soil and locating root impacts), for the same root density. Reg = regular, equidistant distribution (typical of the idealization of root distribution in water uptake models); Clus = cluster or grouped distribution (close to reality, for a plant); Het = heterogeneous (with a non-colonized area because of soil compaction under a track wheel, for example). B. Spatial distribution of the water matric potential in soil resulting from the different types of soil colonization by roots shown in A. It shows areas of unexploited soil for Clus and Het, and strong matric potential gradients. Results are shown for a duration of transpiration corresponding to a few days after the onset of hydric stress experienced by the plant under these different situations of soil colonization. (Source: [Beu+13], reproduced with the permission of PROCEDIA Environmental Sciences ©, all rights reserved). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.4. Simulation of the effect of the spatial distribution of roots in soil on water uptake (continuation). C. Variation of the actual (RET) over potential (PET) evapotranspiration ratio with time for the three types of spatial root distributions shown in Figure 3.3A. It can be seen that Clus and Het arrangements become more limiting for transpiration (RET/PET<1) faster than Reg. (Source: [Beu+13], reproduced with the permission of PROCEDIA Environmental Sciences ©, all rights reserved). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.5. Simulation of the effect of the spatial distribution of roots in soil on water uptake (continuation). D. Variation of the matric potential with time in the bulk soil (soil average) and at the surface of roots, for the three types of spatial root distribution shown in Figure 3.3A. Daily oscillations of the potential are observed at the roots’ surface, which intensify in time with drying out, but also a drop of the potential at the roots’ surface compared to the average value in the bulk soil, especially at night, which shows that the soil is no longer able to sufficiently recharge the rhizospheric zone at night to compensate for daytime uptake. This effect is augmented in the Clus and Het cases. (Source: [Beu+13], reproduced with the permission of PROCEDIA Environmental Sciences ©, all rights reserved). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.6. Virtual root systems, simulated using an architecture model (ArchiSimple, [Pag+14]). A. Taproot system, typical of a dicot species; B. fasciculated root system, as observed in numerous monocot species
Figure 3.7. Tissue development along a root. Tissues become older and more differentiated with distance from the apex. Xylem vessels in A are not functional for transporting water, because they are still full of living cells, whereas in C, xylem cells are dead and the open vessels can transport the water axially. Similarly, the endoderm, which separates the cortex of the central cylinder where the vessels are, has walls that gradually become impervious further from the apex and which thereby decrease the radial conductance. L_r and K_h are, respectively, the hydraulic conductivities of radial and axial water paths in the root. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.8. Variation of axial conductance and radial conductivity along a root, with distance from the apex. The example given is for a main maize root. It should be noted that radial conductance decreases by a factor of 10 between younger (near the apex) and older root segments (near the base), whereas axial conductivity is maximal only at about 30 cm from the apex. These results are based on experiments and models of hydraulic architecture of the root system [DVP98].
Figure 3.9. Simulation of water transfers for a maize root system placed into a non-limiting homogeneous medium (such as hydroponics, water potential = 0 MPa). The model couples a root architecture model and root hydraulic architecture. In A, the water potential of xylem is presented, and in B, water uptake (as a volumetric flux per unit of root surface) is shown. Note the relative homogeneity of the water potential in the xylem, and conversely the flux heterogeneity within the root system. Transpiration is 5 × 10^-3 cm³s^-1 (that is 0.018 L/h). The maize is 43 days old. The image is the projection on a vertical plane of a 3D root system. (Source: [DVP99], modified). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.10. Variation with time of water uptake in a sandy soil along a root system. The experimental system consists of (A) a thin rhizotron filled with translucent sandy soil in which the roots have grown (lupin in this case). When the sandy soil dries out following water extraction by the roots, it becomes more opaque and transmits less light, which enables the imaging of the water content in the rhizotron over time by taking pictures of the backlit system (B). Differences in water content between two times provide access to water uptake between these two times, represented in D over two days, and that can be ascribed to the root system pictured in C on the same scale. The small diagram plotted in red lines (D, bottom left) indicates that we are analyzing here the functioning of a fasciculated root system. The daytime transpiration takes place from 8 h to 20 h, and initially the soil is at field capacity. One may notice the formation of a water extraction front moving with time at depth and laterally over the root system, which is a consequence of the interactions between limitation to transfer in soil and reallocation of uptake by the root hydraulic architecture. (Source: [GDP06]; reproduced with authorization from Plant and Soil ©, all reserved rights). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 3.11. Example of a simulation based on structural–functional modeling of water uptake of two rice genotypes. The genotype E+ is characterized by a twofold production of primary roots compared to E–. Both genotypes are 22 days old, in the same soil (loam), initially at field capacity, and subject to the same transpiration (5 mm/d) during seven days (Doussan C. 2016, unpublished). On top: xylem water potential in the root system of genotypes E– and E+. The water potential in the genotype E– is about twice as low than for E+, approaching the critical threshold of –1.5 MPa (=–15000 cm), where the plant will no longer be able to lower its water potential to take up water. At the bottom: matric potential in soil and at soil/root interface for genotypes E– and E+. Regions of low matric potential (in soil and at soil/root interface) are larger for the genotype E–. On average, the potential at the soil/root interface of genotype E– is more negative –1500 cm compared to genotype E+. Note: color scales are not the same for E+ and E–. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip

4 Preferential Flows

Figure 4.1. Water motion in the direction of the decreasing hydraulic load potential: (a) case of ground water; (b) case of Darcy’s sand column. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 4.2. Water retention characteristics of three soils of different textures. By analogy with the concept of pH, the pF corresponds to the base-10 logarithm of the absolute value of the matric potential, expressed in cm (see equation [1.51])
Figure 4.3. Solute migration in a rectilinear cylindrical pore.
Figure 4.4. Elution of water labeled with tritium and nitrates in a chalk column (hydraulic head: 1.5 m; Péclet number: 67.4); C_t: measured concentration; C₀: injection concentration). Measurements carried out by Pierre Vachier on May 22, 1982
Figure 4.5. Chloride elutions (step signal) on columns saturated with water and composed of soil aggregates of different sizes (average water speed in the column): 2 cm/h (source: [BN62], modified). The arrow indicates on the abscissa the point where the eluted volume reaches the pore volume V
Figure 4.6. Concentration of bromide exiting a lysimeter of silt-clay soil in Villamblain (depth 150 cm). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 4.7. Cell lysimeter.
Figure 4.8. Vertical two-dimensional distribution profiles of a colored tracer (Acid red 1) brought onto silty soil, followed by an irrigation of 10 cm of water. (a) irrigation by sprinkler/undisturbed soil, (b) irrigation by sprinkler/cultivated soil over 30 cm, (c) irrigation by submersion/undisturbed soil and (d) irrigation by submersion/cultivated soil.
Figure 4.9. Response of a drained plot of clay soil to two episodes of rain (on top, in red: rain histogram; in brown with points: drained water ¹⁸O content; in dotted line: rain water ¹⁸O content; in green: drainage flow rate). (Source: [CVD93]). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 4.10. Effect of the presence of macropore on the elution of a bromide peak in a column of glass beads. Top: without macropore; bottom: with a macropore. For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip
Figure 4.11. Macropores coloration using methylene blue.
Figure 4.12. Fingering development during the transition of the infiltration front of a fine sand horizon (50 µm to 100 µm) to an underlying coarse sand horizon (0.5 mm to 1 mm).
Figure 4.13. Effect of compacted areas within a cultivated horizon on water infiltration and bromide transfer in a silt soil. (Source: [Coq+05], modified). For a color version of this figure, see www.iste.co.uk/bourrie/soils3.zip

5 Floods

Figure 5.1. Relationship between old urbanizations and flood-prone areas. (1) Houses and road bordering an alluvial terrace; (2) Establishment on rock topography; (3) Establishment on foothills, of alluvial fan or colluvial areas
Figure 5.2. Topographic relations between the different waterbeds
Figure 5.3. Silting traps in the low valley of the Var, put in place in the 19th Century to constitute new fertile land over the area of the braided average streambed
Figure 5.4. Schematic profile perpendicular to the Aude in its crossing of the low plains, showing the establishment of the old village of Cuxac on the bank rolls and that of the housing estate of the Garrigots in the gutter of the flood flow after breakage of the dikes.
Figure 5.5. Theoretical representation of the optimal spatial organization of a valley. L1 + L2: Natural area of ecological or scenic interest, or leisure; also concerns steep slopes (embankment separating terraces and hillslopes). L3: Agricultural area and flooding expansion area (dynamic slowdown); t: suitable agricultural area; v: hillslope: natural areas + agricultural areas + urbanization? →: possible urban extensions outside flood-prone areas

First published 2018 in Great Britain and the United States by ISTE Ltd and John Wiley & Sons, Inc.

Apart from any fair dealing for the purposes of research or private study, or criticism or review, as permitted under the Copyright, Designs and Patents Act 1988, this publication may only be reproduced, stored or transmitted, in any form or by any means, with the prior permission in writing of the publishers, or in the case of reprographic reproduction in accordance with the terms and licenses issued by the CLA. Enquiries concerning reproduction outside these terms should be sent to the publishers at the undermentioned address:

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The rights of Guilhem Bourrié to be identified as the author of this work have been asserted by him in accordance with the Copyright, Designs and Patents Act 1988.

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ISBN 978-1-78630-217-5

Foreword

ISTE’s scientific publications include a pluridisciplinary editorial sphere entitled “Earth Systems – Environmental Sciences” and, within this domain, we are now pleased to release a series of works entitled Soils, coordinated by Christian Valentin, as part of the activities of the working group on soils at the Académie d’Agriculture de France (French Academy of Agriculture).

The general title of this series of works, “Soils as a Key Component of the Critical Zone” merits a number of comments.

The Critical Zone (CZ), a concept which is now globally recognized, designates the location of interactions between the atmosphere, the hydrosphere, the pedosphere – the outermost layer of the Earth’s crust, made up of soils and subject to the processes for soil formation, derived from interactions with the other surface components – the lithosphere and ecosystems. Within this zone, there are vital exchanges of water, matter and energy, such exchanges interacting with those of other layers, both oceanic and atmospheric, within the Earth system. Its extreme reactivity, whether physical, chemical or biological, is an essential factor of the overall regulation of this Earth system.

Supporting all forms of life, this thin layer has a high level of interaction with human activities. Examples of these are agriculture, urbanization, resource extraction, waste management and economic activities.

This concept of the Critical Zone (CZ) entirely revives the environmental approach, simultaneously enabling an integrated, descriptive, explanatory and predictive view of the Earth system, of its major biogeochemical cycles and their interaction with the climate system. The view becomes dynamic, explaining all interactions, and opens the way for predictive modeling. Such processes are necessarily integrated with given models, paying special attention to the hydrological cycle as well as the carbon and nitrogen cycles.

Within the CZ, soil is a key component, playing a prominent role in the storage, dynamics and conversion of biogenic elements (carbon, nitrogen, phosphorous – C, N, P) and of all inorganic, organic or microbiological contaminants. This contributes to significantly affecting the quantity and the quality of the essential resources for human activity, these being soils, water and air quality.

Soils thus return to the top of the international agenda, as a result of the major challenges for any civilization. These include agricultural production, climate change, changes and conflicts over land use (deforestation, urbanization, land grabbing and others), biodiversity, major cycles (water, carbon (C), nitrogen (N) and phosphorous (P)), pollution, health, waste, the circular economy, and so on. They appear therefore legitimately within the United Nations’ “sustainable development goals” by 2030 (SDG 15: “Protect, restore and promote sustainable use of terrestrial ecosystems, sustainably manage forests, combat desertification, and halt and reverse land degradation and halt biodiversity loss”).

The study of soils, as a key component of the Critical Zone, should thus not only be tackled by soil science but also within the highly numerous disciplines of Earth and life sciences, humanities and social sciences. Soils, being as they are at the center of multiple interactions, are an intricate array of systems, a nexus joining the essential parameters. These are food, water, energy, climate and biodiversity.

Soils, in terms of structure and dynamics, with complex processes, are sensitive to global changes that induce developments, which themselves obey threshold processes and issues of resilience. These involve, with regard to their study, taking into account not only short but also long time spans. This aspect was stressed in a white paper on soils published by the CNRS in 2015 (available at the address: www.insu.cnrs.fr/node/5432). The dynamics of major biogeochemical cycles, in particular with timescale characteristics which can be centuries old, indeed even go further back beyond that and so on.

It is clear that among the major components of the environment discussed earlier, soils are the least understood by the general public, by the authorities and even in academic circles. Consequently, it becomes of prime importance to provide the conceptual bases to the greatest number of university teachers and students so as to tackle soils with the complexity of their nature, their mechanics, their diversity and their interactions with other components, within the Critical Zone.

This is what is achieved with the reflections, analyses and the prospective studies carried out by all of the authors in this series. They are top scientists with a high level of international expertise within their discipline, and are mindful of adopting a holistic approach to soil study. The authors of this series pay specific attention to aspects able to be concluded through an open interdisciplinary science, beyond the single scientific community, policy-makers, managers and to all those who are interested in the evolution of our planet. These authors also support their scientific reflection in line with training demands and, of course, the broadest dissemination of knowledge.

The series takes the form of six volumes:

– Soils as a Key Component of the Critical Zone 1: Functions and Services, a volume which will serve as a general introduction;
– Soils as a Key Component of the Critical Zone 2: Societal Issues;
– Soils as a Key Component of the Critical Zone 3: Soils and Water Circulation;
– Soils as a Key Component of the Critical Zone 4: Soils and Water Quality;
– Soils as a Key Component of the Critical Zone 5: Degradation and Rehabilitation; and
– Soils as a Key Component of the Critical Zone 6: Ecology.

Finally, it is worth mentioning again that this series was prepared essentially within the working group “Soils” at the Académie d’Agriculture de France, under the debonair, yet tenacious and assertive, stewardship of Christian Valentin. We are grateful to this group of scientists and their leader for producing this series.

André MARIOTTI

Professor Emeritus at Sorbonne University

Honorary Member of the Institut Universitaire de France

Coordinator of the series

“Earth Systems – Environmental Sciences”, ISTE Ltd

Introduction

There is no life without water. Without earthly life, there are no soils. Without soils, there is no earthly life. The relationships between water, life and soils are much more than a simple sequence of interactions or interfacing phenomena. They together form a system.

When humans explore the universe in search of other forms of life, be it on the other planets of the solar system – Mars, Jupiter or Saturn’s satellites – or on exoplanets, they look for water in the liquid state or evidence of its past existence, such as a sedimentary stratification, surface formations and evidence of runoff and hydrography.

The particular and fascinating properties of water play a paramount role, especially the hydrogen bond, corresponding to a hidden complex reality that this expression “hydrogen bond” comprehensively explains. Regarding water, as well as soils, and consequently their interactions, one has to constantly shift from continuity to discontinuity.

Liquid water is made up of distinct molecules, but these molecules increasingly interact at a very long distance. The computation of these interactions two by two, three by three, etc., using ab initio methods quickly exceeds calculation possibilities and mean “macroscopic” properties have to be used, as if water were a continuous medium.

Soil scientists slice soils vertically into horizons and laterally into catenas, considered as a whole as “soil cover”. The properties vary continuously but sometimes change in an abrupt way. Transitions can be progressive or brutal. Sometimes, volumetric properties dominate, for example, the water holding capacity, so important for life; sometimes the changes at the boundaries are the dominating ones, for instance, concerning permeability, the soil should be considered as consisting of distinct grains or aggregates and sometimes it is more appropriate to consider it as a continuous medium, even if it is heterogeneous.

Volume 3 of this series, Soils as a Key Component of the Critical Zone 3, is dedicated to water circulation in soils, which is part of quantitative hydrology. Following Chapter 1 on the physical chemistry of the soil–water system, four chapters are devoted to water flows in soils, each time considered in terms of the way in which soils, by their properties, define the future of water: wetting soils or not (Chapter 2), being absorbed by plants (Chapter 3), infiltrating or running off continuously or according to preferential flows (Chapter 4), concentrating or not in certain parts of valleys during floods and causing floods or not, whose catastrophic nature most often is the result of the absence or the inadequacy of preventive measures (Chapter 5).

Volume 4 of this series, Soils as a Key Component of the Critical Zone 4, is dedicated to water quality, which is part of qualitative hydrology. Changes in water quality in soils are the hidden face of pedogenesis (Chapter 1) and influence major biogeochemical cycles at the global scale. The soil solution changes composition, is recharged by dissolved salts and refills groundwater and drinking water resources. Irrigation in semi-arid Mediterranean areas must take into account water quality to avoid soil salinization (Chapter 2). The soil thus constitutes a “transfer system”, and the integrated management of watersheds (Chapter 3) allows, for example, for controlling the flow of particulate and dissolved phosphorus, responsible for cultural eutrophication, and therefore for restoring water quality while protecting soils and what is nowadays globally referred to as their ecosystem services.

At any level of the organization of matter, from the atom to the molecule, and even the whole Earth, none of the discrete elements or continuums approaches (representative volume elements) can on its own provide the solution. One has to shift constantly from one to the other, although they are logically exclusive! This is also true for living beings, sometimes considered individually, sometimes as sets of populations and redundant at times, which overall carry out continuous functions. These biocenoses also live in distinct ecosystems, separated by boundaries, also abrupt or progressive called ecotones. Soil heterogeneity is therefore not a deviation from an ideal homogeneous medium. It is a fundamental characteristic of the soil–water system, in all its physical, chemical and biological components.

Introduction written by Guilhem BOURRIÉ.

Soils and Water Circulation