A Conceptual Model to Predict the Deflation Threshold Shear Velocity as Affected by Near-Surface Soil Water: I. Theory

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DIVISION S-1—SOIL PHYSICS

A Conceptual Model to Predict the Deflation Threshold Shear Velocity as Affected by Near-Surface Soil Water

I. Theory

Wim M. Cornelis^*, Donald Gabriels and Roger Hartmann

Ghent University, Dep. Soil Management and Soil Care, International Centre for Eremology, Coupure links 653, B-9000 Gent, Belgium

^* Corresponding author (wim.cornelis{at}UGent.be).

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
The Interparticle Forces
CONCLUSIONS
REFERENCES

A crucial parameter in predicting wind erosion is the deflationthreshold shear velocity, which is highly dependent on near-surfacesoil water. The empirical and theoretical models to predictthe deflation threshold as affected by near-surface water thathave been reported in literature all suffer from a weak physicalbackground and very large differences between the predictedresults can be observed. The present study was conducted todevelop a new conceptual model to predict the deflation thresholdas affected by near-surface wetness and to contribute to a betterunderstanding of the role of the latter on deflation of sediment.The model was developed by solving the moment balance equationfor entrainment of soil particles by wind, including the momentsassociated with drag forces, lift forces, aerodynamic momentforces, gravitational forces, and interparticle forces due todry and wet bonding. The wet bonding force, which representsthe effect of near-surface soil water, is due to liquid bridgebonding or capillary forces, and adsorbed layer bonding or adhesiveforces. It was related to the particle diameter squared, surfacetension squared and the inverse of matric potential. The latterwas then converted to water content by assuming a logarithmicrelationship, which was shown to be valid between oven drynessand a matric potential of –1.5 MPa, a range that is ofinterest in the light of deflation of soil particles by wind.The conceptual model presented in this paper is relatively simpleand predicts, for a given particle diameter and surface tension,the deflation threshold shear velocity as a function of theratio between water content and the water content at a matricpotential of –1.5 MPa.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
The Interparticle Forces
CONCLUSIONS
REFERENCES

A CRUCIAL PARAMETER in predicting wind erosion is the thresholdshear velocity. This is the minimal shear velocity, which hasto be exceeded to initiate deflation or dislodgment of sedimentby wind shear at the surface. Amongst the several factors thatgovern threshold conditions, near-surface water, which we defineas the water in the few millimeter thick zone just below thesoil surface, is one of the most significant. Through adhesionand capillary effects it strongly contributes to the bindingforces keeping particles together (McKenna-Neuman and Nickling, 1989).

Several studies were conducted to determine the influence ofwater on entrainment of soil or sand particles by wind. Thesestudies mainly resulted in empirical equations relating thenear-surface water content to a deflation threshold, such asthe threshold shear velocity (e.g., Chepil, 1956; Belly, 1964;Hotta et al., 1984; Saleh and Fryrear, 1995; Shao et al., 1996)or a threshold wind velocity measured at a certain height (Azizov, 1977;Chen et al., 1996). McKenna-Neuman and Nickling (1989)proposed a theoretical model, in which they solved the capillaryforce model of Fisher (1926) for cone-shaped sand particles,and simply related the threshold shear velocity of moist sandto the threshold value for dry sand multiplied with a term associatedwith the effect of near-surface water. The latter term was inverselyproportional to the capillary potential. Fécan et al. (1999)extended this model to soils and incorporated the waterretention model of Gardner (1970) into their parameterization.Gregory and Darwish (1990) considered in developing their theoreticalmodel the particle-to-particle bonding force as the sum of thedry and the wet bonding force and incorporated it in a momentbalance equation. They represented the capillary force by thetensile force resulting from diminished pressure as definedby Haines (1925) ignoring the correction introduced by Fisher (1926)for the tension exerted by the interface. As a consequence,their capillary force was proportional to the matric potentialrather than to its inverse as in the models of McKenna-Neuman and Nickling (1989)and Fécan et al. (1999). This resultedin a negative contribution of the capillary potential to thewet bonding force, which is theoretically incorrect (Cornelis and Gabriels, 2003).Gregory and Darwish (1990) further relatedthe matric potential exponentially to the inverse of the ratiobetween water content and water content at a matric potentialof –1.5 MPa. Reviewing and evaluating the most widelyused and the most recent of these models, Cornelis and Gabriels (2003),observed very large differences between the predictedresults. At a water content of 0.5 times the value at –1.5MPa matric potential, the increase in threshold shear velocitypredicted with these models relative to the dry threshold shearvelocity ranged from 117 to 171%. At –1.5 MPa matric potential,the increases ranged from 131 to 261%.

The objective of our study was to develop a new conceptual modelto predict the deflation threshold shear velocity as affectedby near-surface wetness and to contribute to a better understandingof the role of the latter on deflation of sediment. The maindifferences with the models of McKenna-Neuman and Nickling (1989)and Fécan et al. (1999) are that (i) we considered theinterparticle force as the sum of the dry and wet bonding forcesin solving the moment balance equation for entrainment of soilparticles by wind, rather than multiplying the threshold shearvelocity of dry sediment with a factor for near-surface wetness,(ii) we not only considered capillary forces between soil particles(using Fisher's model, 1926), but also took into account adhesiveforces due to adsorbed water films (using Haines' model, 1925),(iii) we applied a water retention model that relates the matricpotential exponentially to the inverse ratio between water contentand the water content at a matric potential of –1.5 MPa,and (iv) we used a more general geometry for particle shapesrather than using cones. The main difference with the modelof Gregory and Darwish (1990) is our approach of both the adhesiveand the capillary force, using respectively the model of Haines (1925)and its correction by Fisher (1926).

The current paper is the first part of two papers on the newconceptual model. In a second part (Cornelis et al., 2004),the model is calibrated and verified using wind-tunnel data.

The Interparticle Forces

TOP
ABSTRACT
INTRODUCTION
The Interparticle Forces
CONCLUSIONS
REFERENCES

The most important forces that bind soil particles to one anotherare electrostatic (Coulomb) forces, van der Waals forces, andforces due to the presence of water, including liquid-bridgebonding (capillary forces) and adsorbed-layer bonding (adhesionforces) (Harnby, 1992).

Interparticle Forces between Dry Particles
For a detailed description of the electrostatic forces and thevan der Waals forces for particles in the two-state phase solid-air,we refer here to Cornelis and Gabriels (2004). In expressinga conceptual model to predict the deflation threshold of dryparticles, they considered the electrostatic force as negligiblein comparison with the van der Waals force. The expression theypresented for the interparticle force of dry platy to sphericallyshaped loose particles F_vdW (N) was:

[1]
whereK_vdW is a proportionality coefficient, and d is the particlediameter (m). Equation [1] can also be written as (Adamson and Gast, 1997):

[2]
where A_H is the Hamakerconstant, and x is the distance between the particles (m). Tabor and Winterton (1968)( 1969) and Israelachvili and Tabor (1972)measured 10.7 x 10^–20 and 13.5 x 10^–20 J, respectivelyas the Hamaker constant for mica. For silica, Hough and White (1980)and Israelachvili (1992) give values of 6.5 x 10^–20and 6.55 x 10^–20 J, respectively.

Interparticle Forces between Wetted Particles
Liquid-Bridge Bonding
The bonding forces between two particles in the three-phasestate solid-air-liquid are, besides the electrostatic and thevan der Waals forces, a result of liquid-bridge bonding andadsorbed-layer bonding. The liquid bridges exert an attractiveforce between particles once they are formed (Harnby, 1992).It is presumed that liquid surface tension causes particlesto adhere to one another when water is present in the pore spacebetween the particles (Kézdi, 1974). The surface of thewater behaves as an elastic membrane as water molecules exertan attraction toward each other. According to Fisher (1926),the liquid bridge formed between two particles exerts a so-calledcapillary force that is the result of (i) the tension exertedby the air–water interface, and (ii) the resultant tensileforce, owing to the hydrostatic pressure in the water beinglower than that in the air, with which the remainder of theparticle is in contact. The capillary force F_C (N) that resultsin a pull between the particles can thus be written as:

[3]
where R₂ is the radius of the ‘waist’of the water wedge (m), ${sigma}$ is the surface tension of the liquid(N m^–1), and ${Delta}$ p is the pressure deficiency between theinternal pressure of the water and the atmospheric pressureexerted on its free surface (Pa) (Fig. 1a). This pressure differenceis given by the Young–Laplace equation:

[4]
whereR₁ is the radius of the air–water interface curvature(m).

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Fig. 1. Particle shape and water wedge according to the (a) isodiametrical sphere model of Fisher (1926), (b) the cone model of McKenna-Neuman and Nickling (free after McKenna-Neuman and Nickling, 1989), and (c) the model proposed in this study.

Equation [3] was solved by Fisher (1926) for an idealized soilconsisting of spherical touching particles of uniform size.Assuming that the air–water interface is a portion ofthe surface of an anchor ring, the total tensile strength wasexpressed as a function of surface tension, particle diameter,and an angle between the normal and the axis of revolution ofthe water wedge at the point of contact. This was actually anexpansion of the model of Haines (1925) who did not considerthe tension due to the air–water interface. Fisher (1926)also made a correction to account for the noncircular profileof the air–water interface, expressing the so-called nodoidof Plateau (1873), that is, the characteristic profile of theliquid bridge between isodiametrical spheres (e.g., De Bisschop and Rigole, 1982,for a thermodynamic solution), as:

[5]
where y is the distance at any point on the air–waterinterface curvature (m), and ${phi}$ is the angle between the tangentto the curve and the axis of revolution (°). The model ofFisher (1926) was later verified through laboratory experimentsby Alberry (1950), and solved for nontouching spheres.

Our purpose was not to express the capillary force as a functionof the curvature of the water wedge, but rather as a functionof the pressure deficiency ${Delta}$ p. Since the atmospheric pressureoutside the water wedge is taken as a reference, ${Delta}$ p is equalto the water pressure in the water wedge p_w. This pressure canbe referred to as capillary potential ${psi}$ _c (Pa) and has hence anegative value. Note that the latter is not equal to matricpotential ${psi}$ _m, which results from both capillary and adsorptiveforces due to a soil matrix (Hillel, 1980). To write the capillaryforce as a function of ${psi}$ _c, y in Eq. [5] should be expressed asa function of ${psi}$ _c. In doing so, McKenna-Neuman and Nickling (1989)substituted cones, which they considered as simple, reasonableapproximations of natural particle contacts, for spheres (Fig. 1b).However, we believe that the application of the cone modelto predict F_C is limited for several reasons. First, the modelderivation is based on simplified geometrical assumptions, wherethe axes of revolution of two touching cones should be in line.In such a case

[6]
and

[7]
wherey₁ and y₂ are the distance from the point of contact of thewater–solid interface to the axis of revolution of thewater waist for cone/particle 1 and 2, respectively, and ${alpha}$ ₁ and ${alpha}$ ₂ are the cone/particle angles. If these axes are not in line,Eq. [6] and [7] do not hold. However, these equalities are thebasis of the cone model for F_C (McKenna-Neuman and Nickling, 1989).Second, when using Eq. [6] and [7] in combination withEq. [5] to derive the geometrical factor G in the model of McKenna-Neuman and Nickling (1989),it appears that the latter is valid onlyif ${alpha}$ ₁ $!=$ ${alpha}$ ₂ and if ${alpha}$ ₁ + ${alpha}$ ₂ > ${pi}$ /2. In all other cases, G becomes zeroand negative, respectively. This would imply that for thosecases, no solution could be found for the capillary force. Third,when using cones, and when assuming that the contact angle betweenwater and the surface of the particle is equal to zero, theangle ${alpha}$ ₁ between the tangent to the water–solid interfaceat contact with cone/particle 1 and the axis of revolution isidentical to the cone/particle angle ${alpha}$ ₁. This is true for cone/particle2 as well. For true shaped particles, the angle ${phi}$ can consistentlydiffer from ${alpha}$ , because (i) the contact angle at the water–solidinterface is most likely different from zero for rough particlesurfaces (Hillel, 1980), (ii) ${phi}$ is affected by the particle geometry,and (iii) ${phi}$ depends on the water content which is related top_w, the parameter that should be solved explicitly. For a givenparticle geometry, ${phi}$ decreases as water content and hence R₁and R₂ increase. Because of these limitations, we left the ideaof representing soil particles as cones, and solved the Young–Laplaceequation as such to R₂.

The differential form of Eq. [4], developed first by Bashforth and Adams (1883)and valid for cylinders or spherical particles,implies that R₁ is related to the third power of R₂. In caseof particles, the proportionality constant is a function ofthe particle diameter squared and hence:

[8]
wherea is a dimensionless proportionality coefficient depending onparticle geometry. Substitution of Eq. [8] into Eq. [4] yields:

[9]

The solution of Eq. [9] to R₂ is a complex function, which canbe simplified to read:

[10]
where bis a factor depending on a, ${sigma}$ , and ${psi}$ _c (m^–2). For ${psi}$ _c greaterthan –1 MPa, which is in the range of water conditionsof interest for deflation of soil particles by wind, the secondand third terms of Eq. [10] become negligibly small. Equation [10]can therefore be simplified to:

[11]
whereK_C^' is a function accounting for soil and fluid properties (m^–2).Substituting Eq. [11] into Eq. [3] results in:

[12]
where K_C = ${pi}$ is a coefficient accounting for soil and fluid properties (m^–2). The finalobtained Eq. [12] differs from the capillary-force model asdeduced by McKenna-Neuman and Nickling model (1989) in thatfor a given surface tension and capillary potential the capillaryforce increases with the square of particle diameter. Furthermore,the geometric parameter K_C is not merely related to the particleangle as in the case of the McKenna-Neuman and Nickling model(1989). It is on the contrary a complex function that can onlybe determined through curve fitting. The model is hence applicablefor all kind of particle shapes (Fig. 1c) and does not pretendto be soluble if particle angle is known.

Adsorbed-Layer Bonding
The adsorbed-layer bonding is caused by the overlapping of theadsorbed layers of neighboring particles. Its strength is proportionalto the tensile strength of the adsorbed film. Packing density,particle shape, particle-size, and particle roughness will thereforeplay an important role (Harnby, 1992). This wet-layer bondingis an adhesion force that includes electrostatic forces, forexample, between diffuse double layers, van der Waals and hydrationforces, responsible for molecular interaction, and forces dueto the overlapping of two interfacial regions, for example,mutual attraction between two clay plates across a slit-shapedpore space (Tuller et al., 1999). The result will be a mutualrepulsion and attraction. These concepts were introduced independentlyby Derjaguin and Landau (1941) and by Verwey and Overbeek (1948),and are often referred to as the DLVO theory. Derjaguin (1957)has termed the repulsive force as the disjoining pressure. Becausein many applications the van der Waals component dominates theother components, only van der Waals forces need to be considered.The above theory applies to smooth particles only. However,a soil consists mainly of rough particles, and the effect ofsurface roughness is to decrease the effective adsorbed layerthickness of the surface by an amount equal to half the averagepeak-to-trough height. This implies not only a decrease in thebinding force but also a minimum adsorbed layer thickness belowwhich interactions are limited to the peaks of roughness (Harnby, 1992).Therefore, the forces due to adsorbed-layer bonding areoften considered as negligible for soil particles (Namikas and Sherman, 1995).It could hence be sufficient to consider onlythe van der Waals force between dry platy to spherically shapedloose particles (Eq. [1]). Notwithstanding this, and since thecontribution of adsorbed-layer bonding to the attraction betweentwo particles increases with water content due to an increasein contact area, we assumed here the force associated with adsorbed-layerbonding F_A (N) to be equal to the tensile strength as definedby the first term in Fisher's equation (Eq. [3]):

[13]
excluding the term for the pressure deficiency,which is associated with the effects of capillarity.

As water content increases, the width of the waist of the waterwedge between the particles R₂ increases. We can therefore assumeF_A to be inversely proportional to the suction in the adsorptionfilms. Since F_A further depends on the contact area betweenthe water films, it is assumed to be proportional to the squareof particle diameter and liquid surface tension as well. Whenusing dimensional analysis, Eq. [13] becomes:

[14]
where K_A is another proportionality coefficientaccounting for soil and fluid properties (m^–2), and ${psi}$ _ais the potential, which is the negative of suction, in the adsorbedlayers (Pa).

Total Wet Bonding Force
When combining Eq. [12] and [14], the interparticle force dueto wet bonding F_AC (N) can be written as:

[15]
whereK_AC is a proportionality coefficient accounting for soil andfluid properties lumping both K_C and K_A together (m^–2),and ${psi}$ _m is the matric potential (Pa). This is a simplified representationof the interparticle force due to wet bonding as it assumesthe effect of the capillary force and adsorptive force to beequal. Of course, below a given matric potential, the adsorptiveforce dominates the capillary force, with the latter being negligible,and hence ${psi}$ _a ${approx}$ ${psi}$ _m in that matric potential range. In the matricpotential range where the capillary force is dominant, the adsorptiveforce is relatively negligible and there, ${psi}$ _c ${approx}$ ${psi}$ _m. Using one singleproportionality coefficient K_AC over the whole matric potentialrange means that the effect of the adsorptive force is overestimatedin our formulation in Eq. [15].

However, combining Eq. [12] and [14] into one formulation enabledus to disregard a minimum soil water as used by Fécan et al. (1999),below which the equilibrium between capillaryand adsorbed water is shifted toward the latter. Further investigationis needed to model this minimum soil water. Note that the upperlimit of F_AC to play a role in keeping particles together isat the point where the individual water wedges at the contactpoints begin to coalescence as water content becomes sufficientlyhigh. The lower limit is at the junction between adsorbed waterand interstitial or structural water. According to Gardner (1986),it is difficult to distinguish between the two categories ofwater and the exact limit depends upon the soil mineralogy.For simplicity, we considered this limit as the water contentat 105°C, that is, at oven dryness.

Matric Potential-Water Content Relationship
Equation [15] shows that it is the matric potential ${psi}$ _m that willdetermine the magnitude of the interparticle force F_AC betweenparticles of moist sediment. However, requirement of matricpotential data forms a key limitation from a practical perspective(Namikas and Sherman, 1995). Standard equipment for measuringmatric potential such as tensiometers are not able to recordthis potential in the uppermost millimeters of the soil thatare exposed to the wind and where the matric potential can bemuch beyond the tensiometer's measuring range. Yet it is thewater condition at low potentials in the uppermost layer ofthe soil that is of primarily concern here. Therefore, matricpotential should be related to water content, a parameter thatcan be determined with much higher precision at the soil surfaceand at low water contents, with such techniques as the gravimetricmethod (dry and weigh method), radio spectrometry, infraredphotography, microwave techniques, or through modeling of soilwater transport as a function of meteorological parameters andsoil type.

In literature, many functions are given to relate water contentto matric potential ${psi}$ _m, such as the well-recognized models ofBrooks and Corey (1964), Campbell (1974), van Genuchten (1980),and Kosugi (1994)(1997). These models are intended to describethe water retention curve over the whole range of water contents,but often give poor results at low water contents. In his recentlypublished book on the physics and modeling of wind erosion,Shao (2000)(p. 297) suggests to use the Brooks and Corey (1964)equation to convert the matric potential in Eq. [15] to watercontent:

[16]
where wis the gravimetric water content (kg kg^–1), w_s is thewater content at saturation (kg kg^–1), w_r is the residualwater content (kg kg^–1), ${psi}$ _mb is the bubbling pressure orair-entry value (Pa), and ${lambda}$ is a dimensionless pore-size distributionindex. As an example, the Brooks and Corey model is fitted inFig. 2 to water retention data for the 300 to 500-µm sizedsandy loam soil aggregates that were used by Cornelis et al. (2004).Although the model fits the data very well (R² = 0.994),the matric potential is not defined if water content becomessmaller than 0.053 kg kg^–1, which is very close to thewater content at a matric potential of –1.5 MPa. Chepil (1956),Gregory and Darwish (1990), and Saleh and Fryrear (1995)reported deflation to cease once the water content exceeds thewater content at –1.5 MPa. The problem with equationssuch as those of Brooks and Corey (1964) is that the residualwater content is defined as the water content where dw/d ${psi}$ _m becomeszero. When determining w_r by curve fitting, this results in ${psi}$ _m = – ${infty}$ MPa at w = w_r (where w_r > 0) in the case of coarseto medium fine soils or well-sorted soils, which is not realistic.For fine or not-well sorted soils, w_r often becomes negativein the curve-fitting procedure. As a negative water contentis undefined, w_r is then forced to converge to zero, and thisresults as well in an unrealistic path of the retention curveat low water contents. The Shao's (2000) idea that "It is possibleadvantageous for wind-erosion modeling to use the well-establisheddata sets for the soil hydraulic parameters w_s, w_r, ${psi}$ _mb, and ${lambda}$ ..." in the context of predicting the effect of soil wateron deflation of sediment is therefore premature. Shao (2000)further assumed w_r to be equal to the air-dry water content,which is, from a physical point of view acceptable. Indeed,at water contents below the air-dry value, deflation will probablybe strongly reduced depending on the ambient relative humidity.However, air-dry water content is in most cases different fromthe w_r value when the latter is simply determined by curve fitting.The air-dry water content of the 300- to 500-µm sizedsandy loam soil aggregates was 0.014 kg kg^–1 (Cornelis et al., 2004),which is about a factor of four lower than theresidual water content as obtained from curve fitting the Brooks and Corey (1964)equation to the data given in Fig. 2. It shouldbe mentioned that the curve-fitted value for w_r strongly dependson the data range used. In most studies, the matric potentialranges between 0 and –1.5 MPa, which is the range on whichw_r values found in databases are generally based.

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Fig. 2. Observed water retention data of the 300- to 500-µm sized sandy loam aggregates, and the fitted Brooks and Corey model (1964; Eq. [16]), and the Rossi and Nimmo model (1994; Eq. [17]).

According to Rossi and Nimmo (1994), the water content becomesapproximately proportional to the logarithm of matric potentialin the dry range of the water retention curve, where the above-mentionedwater retention models seem to be inappropriate. When includingthe Ross et al. (1991) correction that forces the model to convergeto zero water content at a matric potential of about –10³MPa at oven dryness, their "three parameter sum model" for matricpotential as a function of water content was written as (Rossi and Nimmo, 1994):

[17]
where ${psi}$ _mi is the matric potential at the junction point where the twocurves join (Pa), ${psi}$ _md is the matric potential at oven dryness( ${approx}$ –10³ MPa), and ${alpha}$ and ß are shape parametersthat are determined by the conditions that ensure the continuityof both Eq. [17] and its first derivative to ${psi}$ _mi. The readeris referred here to Rossi and Nimmo (1994) for more details.The main advantage of Eq. [17] is that it gives a realisticpath of the water retention curve at matric potentials lowerthan those at –1.5 MPa. In Fig. 2, the "three parametersum model" as proposed by Rossi and Nimmo (1994) is fitted tothe data and R² was 0.994 as well. Such a curve is, however,not widely used because of its rather complex shape.

Since particle entrainment by wind already stops at rather lowwater contents (Chepil, 1956; Gregory and Darwish, 1990), wepropose only to use the logarithmic part of the Rossi and Nimmomodel (1994) that is applicable in the dry range of the curve.Campbell and Shiozawa (1992) and Schofield (1935) measured watercontents of soils ranging from sand to silty clay at matricpotentials far beyond ${psi}$ _m = –1.5 MPa. Inspection of theirdata indicate a loglinear relationship between matric potentialand water content for matric potentials smaller than approximately–0.03 and –1 MPa for sand and silt loam, respectively,which were the extreme values in their data set. Their siltyclay soil showed an intermediate value. Since, for the givensoils, these extreme matric potential values correspond to volumetricwater contents ranging from, respectively, approximately 0.05m³ m^–3 to approximately 0.15 m³ m^–3, it is plausibleto represent that matric potential that determines the effectof water on the threshold shear velocity, by a single logarithmicequation.

The expression we propose for matric potential as a functionof water content, and which should be valid within the above-mentionedwater content range that is of importance to predict the deflationthreshold shear velocity, is:

[18]
wherec is a dimensionless regression coefficient accounting for soilproperties. Since Eq. [18] is valid for matric potentials smallerthan at least –1 MPa, the coefficient c can be relatedto the water content at –1.5 MPa w_1.5, a reference watercontent that is, though rather arbitrary when considering deflationof soil particles, often available in soil data bases such asthose mentioned by Shao (2000), or that else can be predictedfrom pedotransfer functions. Cornelis et al. (2001) demonstratedthat the functions of Vereecken et al. (1989) are relativelyaccurate to estimate water content at a matric potential of–1.5 MPa. With

[19]

Eq. [18] becomes:

[20]

Use of Eq. [15], rather than using Eq. [12] and [14] separately,has the advantage that a single relationship between matricpotential and water content such as Eq. [20] can be used. However,further investigation is needed to find simple equations torelate capillary potential and adsorptive potential to watercontent separately. Promising work on this has been undertakenby Or and Tuller (1999). Their theories were not consideredhere to keep the threshold shear velocity model as simple aspossible.

A General Model for the Deflation Threshold Shear Velocity of Dry and Wetted Particles
A particle resting on a surface bed and exposed to a fluid streamexperiences several forces: a horizontal-drag force F_D, a liftforce F_L, an aerodynamic-moment force F_M, the gravitationalforce F_G and an interparticle force F_Ip (Iversen et al., 1976).The interparticle force F_Ip can be written as:

[21]
which is the sum of Eq. [1] and[15].

The gravitational force F_G, or the particle weight, should beaugmented with the weight of the water film that is formed aroundthe particles. The weight of the particle with its water filmwill increase with water content:

[22]
where K_G is a dimensionless proportionalitycoefficient (= ${pi}$ /6 for ideally spherical, smooth particles), ${rho}$ _s is the particle density (Mg m^–3), ${rho}$ _f is the fluid density(Mg m^–3), and g is the gravitational acceleration (m s^–2).

The aerodynamic forces can be defined as (Cornelis and Gabriels, 2004):

[23]

[24]

[25]
whereK_D, K_M, and K_L are dimensionless proportionality coefficients,and u_*t is the threshold shear velocity (m s^–1).

At the instant of particle motion, the aerodynamic forces F_D,F_L, and F_M will exceed the retarding forces F_G and F_Ip, andthe particle will pivot about a downstream point of contact.At the instant of deflation, the moments are balanced:

[26]
where a', b', and c' are momentarm lengths (m). When substituting Eq. [1], [15], and [22] to[25] into Eq. [26] and with a' = a₁d, b' = b₁d, and c' = c₁d,the threshold shear velocity u_*_t or u_*_tw in the case of moistsediment, becomes:

[27]
whichcan be simplified to

[28]
where

[29]

When grouping the different coefficients in Eq. [29] that areconstant for a given soil as:

[30]

[31]

[32]
andapplying Eq. [20], the coefficient A can be written as:

[33]

The values for the parameters A₁ and A₂ were determined by Cornelis and Gabriels (2004)using dry-sediment data and were 0.013 and1.7 x 10^–4 N m^–1, respectively. Both the coefficientsK_AC and K_vdW depend on particle shape, particle diameter, particleroughness, and interparticle distance, and A₃ is therefore ageometry factor. Unless it is possible to quantify particleshape, particle diameter, particle roughness, and interparticledistance of a given bulk soil, A₃ should be determined by curvefitting. Cornelis et al. (2004) found A₃ to be equal to 3 x10¹⁴ N^–1 m^–1.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
The Interparticle Forces
CONCLUSIONS
REFERENCES

Near-surface soil wetness is generally considered as an importantfactor in determining the onset of wind erosion. However, untilnow its effect was not well understood and when consulting internationalliterature, very large differences can be observed between experimentalresults. In this study, existing theories on liquid bridge bondingand adsorbed layer bonding were reanalyzed. The model of Fisher (1926)for capillary forces F_C, which are responsible for liquid-bridgebonding, was applied to express these forces as a function ofcapillary potential ${psi}$ _c. The Young–Laplace equation wassolved to relate the radius of the waist of the water wedgebetween two particles to capillary potential. By imposing someassumptions, the capillary force was expressed as F_C = K_C ${sigma}$ ²d²/| ${psi}$ _c|, where K_C is a proportionality coefficient accountingfor soil and fluid properties, ${sigma}$ is the liquid surface tensionof the liquid and d is particle diameter. Although adsorbed-layerbonding is often considered as negligible for soil particles,a function similar to the capillary-force model was proposedfor the adsorption force F_A by considering tensile strengthonly: F_A = K_A ${sigma}$ ² d²/| ${psi}$ _a|, where K_A is another proportionalitycoefficient accounting for soil and fluid properties, and ${psi}$ _ais the potential due to adsorptive forces. The interparticleforce due to wet bonding was then written as F_AC = K_AC ${sigma}$ ² d²/| ${psi}$ _m|,where K_AC is a proportionality coefficient accounting for soiland fluid properties lumping both K_A and K_C together, and ${psi}$ _mis the matric potential. Although this expression is a simplifiedrepresentation of the interparticle force between particlesof wetted sediment, we believe that this hypothesis is sufficientlyappropriate for wind-erosion prediction.

Since determination of matric potential is a key limitationfrom a practical perspective, it was related to gravimetricwater content w. A logarithmic relation was assumed includinga correction to force the model to converge to zero water contentat oven dryness ( ${psi}$ _m ${approx}$ –10³ MPa). It was shown by consideringdata from literature that such relation described the waterretention curve very well at matric potentials that are of interestin the light of deflation of soil particles. Matric potentialwas then expressed as a function of water content includingonly one unknown parameter, viz. water content at –1.5MPa w_1.5.

The wet-bonding force was incorporated into a moment balanceequation for entrainment of soil particles by wind, includingthe moments associated with a drag force, a lift force, an aerodynamicmoment force, the gravitational force, and an interparticleforce due to dry and wet bonding. A conceptual model for thresholdshear velocity, which included only one unknown proportionalitycoefficient A₃ for the effect of wetness, was finally established.A primary advantage of our approach was that water content wasindexed to matric potential by using w_1.5 only, a parameterthat can be rather easily determined. It was also pointed outthat widely accepted equations for the water retention curvesuch as the models of Brooks and Corey (1964) are not applicableto predict deflation of soil particles as they fail to describethe water retention curve at water conditions below –1.5MPa.

The advantage of relating the interparticle force to matricpotential rather than to the capillary force and the adsorptiveforce separately, was that a minimum water content below whichthis force is dominant, could be disregarded. Furthermore, itallowed considering a single equation to relate potential towater content, which resulted in a relatively simple thresholdshear velocity model.

Received for publication April 4, 2003.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
The Interparticle Forces
CONCLUSIONS
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