Soil physical quality of Mollisols quantified by a global
					index

Ghiberto, Pablo Javier; Imhoff, Silvia; Libardi, Paulo Leonel; Silva, Álvaro Pires da; Tormena, Cassio Antonio; Pilatti, Miguel Ángel

doi:10.1590/0103-9016-2013-0414

Abstract

Indicators synthesizing the state of the structural quality and the function of the porous system are useful for assessing soil production capacity as well as the way it may serve natural ecosystems. This research aimed (i) to determine indicators of the state and function of the porous system, (ii) to use them to derive a global index to characterize the soil physical quality, and iii) to establish a reference pore-size distribution curve for Mollisols from the province of Santa Fe (Argentina). Sixty water retention curves (WRC) of A and B horizons of Mollisols, with clay varying between 119 and 538 g kg⁻¹, organic matter between 5 and 40 g kg⁻¹, and soil bulk density between 1.09 and 1.49 Mg m⁻³, were used. The indicators measured were: pore size distribution, macroporosity (POR_p), air capacity (AC_t) and plant-available water capacity (PAWC) among others. Soils were classified into four groups according to their physical properties and a reference WRC was determined. From this WRC and considering a total porosity of 0.514 m³ m⁻³, POR_p was 0.035 m³ m⁻³, AC_t 0.153 m³ m⁻³, field capacity 0.361 m³ m⁻³, permanent wilting point 0.136 m³ m⁻³ and PAWC 0.225 m³ m⁻³. Both the high silt content and low organic matter content confer on the soil characteristics with low stability, excess of small pores and low porosity of the macropore domain. Consequently, the capacity to quickly drain the water excess and allow root proliferation was not optimal, possibly due to the high silt or clay content and the low sand content, characteristic of the soil matrix of these Mollisols.

water release curve; silty-loam; macropore; soil management

Introduction

Soil organic matter, soil structure and the porous system are key attributes of the regulation of water flow, nutrient supply, contaminants adsorption and desorption, and leaching losses as well as gas emissions (Bronick and Lal, 2005Bronick, C.J.; Lal, R. 2005. Soil structure and management: a review. Geoderma 124: 3-22.; Clothier et al., 2008Clothier, B.E.; Green, S.R.; Deurer, M. 2008. Preferential flow and transport in soil: progress and prognosis. European Journal of Soil Science 59: 2-13.; Dexter, 2004a)Dexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.. Soil structure conditions influence the pore size distribution that can be described by means of the soil water retention curve (WRC). Pores draining up to the inflection point of the WRC are structural pores whereas the remainder correspond to textural pores, which are conditioned by soil microstructure (Dexter, 2004aDexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.). This author suggested using the S index to quantify soil structural quality and demonstrated that it can be used when assessing soil management practices, as it identifies areas of degradation or improvement in the soil physical conditions (Dexter, 2004aDexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.,bDexter, A.R. 2004b. Soil physical quality. Part II. Friability, tillage, tilth and hard-setting. Geoderma 120: 215-225.,cDexter, A.R. 2004c. Soil physical quality. Part III: Unsaturated hydraulic conductivity and general conclusions about S-Theory. Geoderma 120: 227-239.; Dexter and Czyz, 2007Dexter, A.R.; Czyz, E.A. 2007. Applications of S-theory in the study of soil physical degradation and its consequences. Land Degradation and Development 18: 369-381.).

Other indicators have been suggested by Reynolds et al. (2009)Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263. to express either directly or indirectly the state and/or function of porous space: macroporosity, porosity in the matrix domain, air capacity, air capacity in the soil matrix, plant available water capacity, and pore fraction with a diameter, identified either as less or more than 30 µm. By using these indicators they determined an “optimal” pore size distribution, allowing them to study various combinations of soil management practices. Additionally, they characterized pore distribution curves by mode, mean, median, skewness, dispersion and kurtosis. The authors concluded these indicators, together with the S index, are very useful for quantifying the physical properties of rigid or moderately expansive agricultural soils.

In the Mollisols of Santa Fe, one of the main productive regions in the humid Pampas in Argentina, neither were the above mentioned indicators studied nor a WRC of reference determined, both of which could have been used to distinguish which management techniques promote the improvement or degradation of soil. Due to the importance of establishing these indicators, the aims of this study were: (i) to determine indicators of the state and function of the porous system, (ii) to use them to derive a global index to characterize the soil physical quality, and (iii) to establish a reference pore-size distribution curve for Argiudolls and Hapludolls of the province of Santa Fe, (Argentina).

Materials and Methods

For this study, Argiudolls and Hapludolls representative (INTA, 2014Instituto Nacional de Tecnología Agropecuaria [INTA] 2014. GeoINTA viewer: soil maps, soil profiles and soil coverage, images and georeferenced databases = Visor GeoINTA: mapas de suelo, perfiles y coberturas de suelos, imágenes y bases de datos georeferenciadas. Available at: http://geointa.inta.gov.ar/visor2/?p=96 [Accessed Jul 11, 2014] (in Spanish).
http://geointa.inta.gov.ar/visor2/?p=96... ) of those found in the province of Santa Fe (Argentina), with wide variations in texture, organic matter content (OM) and bulk density (ρ_b), were selected (Figure 1, Table 1). For each soil, different soil management conditions were studied so that considerable variability in soil physical properties would be obtained. In each case, disturbed soil samples were collected and used to determine organic carbon by Walkley and Black’s method (Jackson, 1982Jackson, M.L. 1982. Soil Chemical Analysis. = Análisis Químico de Suelos. Omega, Barcelona, Spain (in Spanish).) which were converted to OM by multiplying by 1.724. Particle size and particle density (ρ_p) analyses were carried out by the Bouyoucos hydrometer and pycnometer methods according to Gee and Bauder (1986)Gee, G.W.; Bauder, J.C. 1986. Particle size analysis. p. 383-411. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA. and Blake and Hartge (1986a)Blake, G.R.; Hartge, K.H. 1986a. Particle density. p. 377-382. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA., respectively.

Figure 1
− Soil sampling sites where different soil management conditions were studied. References: 1) Typic Haplustoll, Cuatro Bocas; 2) Typic Argiudoll, Villa Minetti; 3) Aquic Argiudoll, Margarita; 4 and 5) Aquic Argiudoll, Angeloni; 6) Typic Argiudoll, San Justo; 7) Typic Argiudoll, Rincón de Ávila; 8) Aquic Argiudoll, Humboldt; 9) Aquic Argiudoll, Recreo; 10 and 11) Typic Argiudoll, Esperanza; 12) Typic Argiudoll, Loma Alta; 13) Typic Argiudoll, Chabás; 14) Typic Argiudoll, Chovet; 15) Typic Argiudoll, Murphy; 16 and 17) Typic Hapludoll, Santa Isabel; 18) Entic Hapludoll, Saforcada.

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Table 1
− Content of organic matter (OM), texture and soil bulk density (ρb) of the Mollisols studied.

Undisturbed soil samples with stainless steel 100 cm³ cylinders (diameter 5 cm and height 5 cm) were collected at each sampling site to determine the WRCs of A (n = 30) and B (n = 30) horizons. These samples (n = 780) were submitted to the following water potentials: -10, -20, -30, -40, -50, -60, -80, -100 cm of water column in a tension table, and -600, -1,000, -3,000, -6,000 and -15,000 cm of water column in a Richards’ pressure chamber (Klute, 1986Klute, A. 1986. Water retention: laboratory methods. p. 635-660. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.). Then, the samples were oven-dried and used to determine the ρ_b(Blake and Hartge, 1986bBlake, G.R.; Hartge, K.H. 1986b. Bulk density. p. 363-375. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/SSSA, Madison, MI, USA.). WRCs that cover at least a range of tension from 10 to 15,000 cm of water column can be used to analyze structural and textural porosity, and consequently the structural condition of the soils (Dexter et al., 2008Dexter, A.R.; Czyz, E.A.; Richard, G.; Reszkowska, A. 2008. A user friendly water retention function that takes account of the textural and structural pore space in soil. Geoderma 143: 243-253.). This approach was adopted in this study.

Water content data on mass and volume bases were adjusted to equation (1) (van Genuchten, 1980Genuchten, M.T. van. 1980. A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal 44: 892-898.) by using the RETC program Version 6.0 (van Genuchten et al., 2007Genuchten, M.T. van; Simunek, J.; Leij, F.J.; Sejna, M. 2007. Code for quantifying the hydraulic functions of unsaturated soils – RETC Version 6.0. US Salinity Laboratory, Riverside. Available at: http://www.pc-progress.com/en/Default.aspx [Accessed Sep 5, 2011]
http://www.pc-progress.com/en/Default.as... ).

where: θ_gs is the gravimetric saturation water content (kg kg⁻¹); θ_gr is the gravimetric residual water content (kg kg⁻¹); α is inversely related to the bubbling pressure, (cm⁻¹), n and m = (1-1/n) are adjustment parameters and h is the absolute value of the matric potential. Then, subscript “v” will be used to indicate volumetric water content and differentiate it from subscript “g” which stands for gravimetric water content.

WRCs, both in their gravimetric and volumetric form, were normalized, by using equation (2).

Θ being the normalized water content, also called the effective saturation.

From these curve indicators suggested by Reynolds et al. (2002)Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146., Dexter (2004a) and Reynolds et al. (2009)Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263. namely: pore size distribution curve, S index (S_gi), macroporosity (POR_p), porosity of the soil matrix domain (POR_m), air capacity (AC_t), air capacity of the soil matrix (AC_m), plant-available water capacity (PAWC), diameter pore fraction less (FC/POR_t) or more (AC_t /POR_t) than 30 µm were determined.

Pore volume distribution curve

The pore-volume distribution curve for each soil was calculated from the first derivative of equation (1) using the volumetric water content, θ_v (m³ m⁻³), versus ln(h), and plotted against the equivalent pore diameter (d_e), on a log₁₀ scale (Equation 3). The effective pore diameter was described by the equation of capillarity (Libardi, 2005Libardi, P.L. 2005. Dynamics of Soil Water = Dinâmica da Água no Solo. EDUSP, São Paulo, SP, Brazil (in Portuguese).), as shown in equation (4), and was used to describe the pore volume distribution function

where: S_v(h) is the slope of the soil WRC as a function of tension (h); γ = 72.8 gm s⁻² the surface tension of water, ω≈0 the water-pore contact angle, ρ_w= 0.998 g cm⁻³ the water density and g = 980 cm s⁻²the gravitational acceleration.

To make the curves comparable, the normalized pore distribution S*(h) was obtained by dividing S_v(h) by S_vi:

where: S_vi is the slope of the tangent at its inflection point which was calculated in the soil WRC, S_vi(h), using equation (6):

Pore-size frequency curves were compared by using measurements of the central tendency and the spread of the curves (Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.). Measurements of the central tendency of each evaluated pore frequency distribution curve were the median (d_median) and the mode (d_mode) calculated as:

Also the geometric mean (d_mean), standard deviation (SD), skewness and kurtosis of the pore frequency distribution curves were studied as presented in equations 9, 10, 11 and 12.

Dexter's Sgiindex

By using soil WRCs adjusted to the gravimetric water content the S_gi index was calculated as suggested by Dexter (2004a)Dexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.. For that purpose equation 6 was used and the soil water potential at the point of inflection of each curve (h_gi) was determined as:

Macroporosity and Porosity of the Soil Matrix Domain

Macroporosity (POR_p, m³ m⁻³), corresponding to pores more than 300 µm in diameter (Dexter and Czyz, 2007Dexter, A.R.; Czyz, E.A. 2007. Applications of S-theory in the study of soil physical degradation and its consequences. Land Degradation and Development 18: 369-381.; Dexter et al., 2008Dexter, A.R.; Czyz, E.A.; Richard, G.; Reszkowska, A. 2008. A user friendly water retention function that takes account of the textural and structural pore space in soil. Geoderma 143: 243-253.), was calculated as:

where: POR_t= (1-ρ_b/ρ_p) is the total soil porosity calculated (m³ m⁻³) and θ₁₀ the volumetric water content corresponding to the tension of a 10 cm water column (m³ m⁻³). Porosity in the domain of the soil matrix (POR_m, m³ m⁻³), corresponding to soil water content with pores less than 300 µm in diameter was estimated by using soil WRCs:

Although there is no agreement in the literature about the best value for distinguishing macropores from matrix pores (Perret et al., 1999Perret, J.; Prasher, S.O.; Kantzas, A.; Langford, C. 1999. Three-dimensional quantification of macropore networks in undisturbed soil cores. Soil Science Society of America Journal 63: 1530-1543.; Chen et al., 1993Chen, C.; Thomas, D.M.; Green, R.E.; Wagenet, R.J. 1993. Two-domain estimation of hydraulic properties in macropore soils. Soil Science Society of America Journal 57: 680-686.), we used the selected pore diameters due to the water and air storage characteristics which are very different. Thus, these pore sizes can be used for distinguishing different soil quality conditions (Reynolds et al., 2002Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146.).

Air Capacity and Air Capacity of Soil Matrix

Air capacity (AC_t, m³ m⁻³) was estimated from the total porosity calculated from θ_100;the volumetric water content corresponding to the tension of a 100 cm water column.

Soil matrix air capacity was calculated by the equation:

AC_m is the porosity corresponding to pores more than 30 µm and less than 300 µm in diameter.

Plant-available water capacity

For this purpose field capacity values (FC) were estimated, considering them as volumetric water content at a tension of 100 cm, and the permanent wilting point (PWP), was estimated as volumetric water content at a tension of 15,000 cm. Plant-available water capacity (PAWC) was estimated as: PAWC = FC-PWP (Veihmeyer and Hendrickson, 1949Veihmeyer, F.J.; Hendrickson, A.H. 1949. Methods of measuring field capacity and permanent wilting percentage of soils. Soil Science 68: 75-94.). Finally the pore fraction with a diameter less (FC/POR_t) than and the pore fraction with a diameter more (AC_t/POR_t) than 30 µm were calculated as indicated by Reynolds et al. (2002)Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146..

The tension of 100 cm was used to define the field capacity water content due to pores with diameters < 30 µm and are considered as storage pores that contain water available for plants. In addition, these pores are influenced by texture and organic C content but not by increases in soil bulk density (da Silva and Kay, 1997Silva, A.P.; Kay, B.D. 1997. Effect of soil water content variation on the least limiting water range. Soil Science Society of America Journal 61: 877-883.; Kay and Angers, 2000)Kay, B.D.; Angers, D.A. 2000. Soil structure. p. A229-A276. In: Sumner, M.E., ed. Handbook of soil science. CRC Press, Boca Raton, FL, USA..

Structural stability index

The risk of structural degradation was assessed by the “structural stability index” (SI) (Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.) calculated as:

where: OM is the organic matter content (g kg⁻¹); clay and silt are granulometric fractions (g kg⁻¹).

Global Index of soil physical quality

An index with a range between 0 and 1 was assigned to each attribute (OM, ρ_b, S_gi, AC_t, POR_p, PAWC, FC/POR_t and SI) according to the value obtained for each horizon. A value of 1 stands for the optimal condition for the attribute and 0 for the most limiting condition. As the value decreases, the condition becomes more unfavorable. The indexes between 1 and 0 were established taking into account the reference values mentioned in the literature for each parameter (Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.). Once all indexes were obtained, they were summed to produce the horizon score considering 8 as the maximum value, whereby eight attributes with an index of 1 each equals 100 %.

Five horizons with the highest score were used to draw an average WRC considered as an “average reference curve” for horizons with good structural quality. Additionally, the confidence interval for each normalized water content (Q ± s) was calculated, generating a curve with minimal values and another with maximal values. For each one of these two curves d_mean, d_mode, d_median, SD, skewness and kurtosis parameters were determined, establishing a reference interval used to describe the shape of the curves and the pore frequency distribution of the horizons studied.

Relationships between indicators were studied using linear regression models in which the coefficient of determination (r²) and statistical significance (p< 0.05) of the correlation were evaluated. In order to verify whether granulometric fractions, ρ_b and OM content affected S_givalues, a multiple regression analysis was carried out using a “stepwise” selection procedure (SAS, Statistical Analysis System, version 5.0, 1991). Analogously the relationship between structural quality index, SI, with ρ_b, POR_t, S_gi, POR_p, POR_m, AC_t, AC_m, FC, PWP, PAWC, FC/POR_t and AC_t/POR_twas analyzed.

Results and Discussion

Soil physical quality indicators

Only 14 A horizons showed values between 30 and 50 g kg⁻¹ organic matter. All others presented lower values. Despite the wide particle size variation in the soils studied, an increase in ρ_b was observed when OM decreased (Figure 2).

Figure 2
− Relationship between soil bulk density (ρb) and organic matter content (OM).

Soil bulk density in A horizons was lower than the critical density estimated according to Daddow and Warrington (1983)Daddow, R.L.; Warrington, G.E. 1983. Growth-limiting soil bulk densities as influenced by soil texture. USDA Forest Service, Fort Collins, CO, USA. (WSDG Report. WSDG-TN-00005)., even when various researches have demonstrated that small ρ_bincreases can cause root growth reductions even if they are below the critical limit. Total porosity of the soil (POR_t) was between 0.432 and 0.567 m³ m⁻³. When analyzing air capacity (AC_t) corresponding to pores with diameters more than 30-µm diameter, the low values observed, especially in the B horizon, indicated evidence of the difficulties of these soils in terms of fluid flows. This indicator suggests the existence of reduced air volume to be used after heavy rainfall and confirms aeration problems found in different studies in the least limiting water range (Damiano and Moschini, 2011Damiano, F.; Moschini, R.C. 2011. Least limiting water range in Argiudoll soils under Eucalyptus dunnii maiden. Ciencia del Suelo 29: 1-11 (in Spanish, with abstract in English).; Miretti et al., 2010Miretti, M.C.; Imhoff, S.; Silva, A.P.; Lavado, R. 2010. Soil structure degradation in patches of alfalfa fields. Scientia Agricola 67: 604-610.).

Macroporosity (POR_p) was low. The POR_p geometric mean of all values in A horizon was 0.032 m³ m⁻³ and in B horizons 0.010 m³ m⁻³. Considering the optimal value of 0.07 m³ m⁻³(Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.), in 42 cases, values were below this index and in 31, lower than 0.04 m³ m⁻³. Thus, in the soils studied the capacity to rapidly drain excess water and allow for root proliferation is not optimal due to the high content of silt or clay, the low sand content and the presence of occluded pores that are typical of the matrix in these soils (Taboada et al., 2008Taboada, M.A.; Barbosa, O.A.; Cosentino, D.J. 2008. Null creation of air-filled structural pores by soil cracking and shrinkage in silty loamy soils. Soil Science 173: 130-142.).

Physical quality degradation in these soils exacerbates these problems as evidenced in Argiudolls and Hapludolls irrigated with sodic-bicarbonated waters and in Argiudolls when conventional tillage or no-till systems were applied without the inclusion of adequate rotations (Pilatti et al., 2006Pilatti, M.A.; Imhoff, S.; Ghiberto, P.J.; Marano, R.P. 2006. Changes in some physical properties of Mollisols induced by supplemental irrigation. Geoderma 133: 431-443.; Ghiberto et al., 2007Ghiberto, P.J.; Pilatti, M.; Imhoff, S.; Orellana, J.A. 2007. Hydraulic conductivity of Molisolls irrigated with sodic-bicarbonated waters in Santa Fe (Argentina). Agricultural Water Management 88: 192-200.; Imhoff et al., 2010Imhoff, S.; Ghiberto, P.J.; Grioni, A.; Gay, J.P. 2010. Porosity characterization of Argiudolls under different management systems in the flat Pampas of Argentina. Geoderma 158: 268-274.).

Small pore predominance was exhibited when evaluating the pore fraction of pores with less (FC/POR_t) and more (AC_t/POR_t) than 30-µm diameters. Only in 13 cases, all in the A horizon, did FC/POR_t show values between 0.6 and 0.7. In 43 of all 60 cases this indicator was over 0.7 evidencing aeration and nitrate production problems due to the scarce amount of more than 30-µm diameter pores present (Reynolds et al., 2002Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146.). The effect was noticeable in B horizons and both parameters presented a correlation with ρ_b as shown in Figure 3.

Figure 3
− Relationship between the fraction containing lower than 30 µm diameter pores (FC/PORt) and soil bulk density (ρb).

S_gi indicator variations ranged between 0.024 and 0.077 in A horizons and between 0.021 and 0.049 in B horizons (Table 2). Considering that the structural stability index SI > 9 % indicates a stable soil structure, 7 % < SI < 9 % a low degrading risk, 5 % < SI < 7 % a high degrading risk, SI < 5 % structurally degraded soils (Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.) , in 52 out of the 60 cases the value was SI < 5 %. This situation is a consequence of the high silt and clay content and the low organic matter proportion in the soils studied. On the other hand, SI was 10.8 when silt and clay content were 156 and 119 g kg⁻¹ respectively; this Hapludoll representing an extreme case among all soils analyzed because of its granulometry (sandy loam). Based on these considerations, the S_gi index was shown to be consistent with the results obtained, showing higher values with an increase in SI.

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Table 2
− Indicators of physical quality used to group the soils in categories.

Taking into account the global index obtained for each horizon from OM, ρ_b, S_gi, AC_t, POR_p, PAWC, FC/POR_t and SI attributes, horizons could be organized into four groups presenting the following general characteristics.

Group 1 - With a score above 70 %, horizons show more than 15 % higher than 30 µm (AC_t) diameter pores and macroporosity (POR_p) higher than 7 %. The FC/POR_t index is between 0.6 and 0.7, which ensures a proper balance between air and water supply. In these cases OM content ranged from adequate to optimal and was associated with good structural stability rates (SI). S_gi was between 0.035 and 0.05, indicating good physical quality. In soils with a high sand content and without a good capacity for water retention values were S_gi > 0.05.

Group 2 -Scoring between 50 and 70 %, AC_t continued at levels above 15 % but POR_p levels were lower than in the previous group, with values between 4 and 7 %. Horizons in this group appear to undergo structural degradation, a situation probably originated by the decrease in OM associated with the high silt content that is characteristic of the parent material of the Mollisols studied.

Group 3 -With a score below 50 %, their AC_t is lower than 15 % and their POR_p below 4 %, evidencing serious problems of air supply and water percolation.

Group 4 - B horizons have less than 10 % higher than 30 µm diameter pores and less than 4 % higher than 300 µm higher diameter pores, except for some horizons with over 15 % sand, the score being approximately 40 in these cases. For A horizons to surpass a score of 40 they should have approximately 3 % OM and lower than 1.3 Mg m⁻³ρ_b, to compensate for the increased silt content in those horizons. Soils presenting B horizons with a score of about 40 (the highest one obtained in B horizons) would be the most productive ones and would be characterized by having a higher sand content and lower silt content than the rest, which seems to compensate for the lower OM content in A horizons of a similar score.

Water Retention Curves

Normalized water retention and pore distribution curves corresponding to A and B horizons of Mollisols were studied together with the reference curve (Figure 4). The reference curve of A and B horizons was fitted to α = 0.053 cm⁻¹, n = 1.1988 and m = 0.1658 parameters, and was characterized by the values of d_mode that occurred at 72 % of saturation and a tension of h = 84.5 cm, d_median that took place at 50 % saturation and h = 609 cm, and d_mean with h = 1,544 cm. As described by Blott and Pye (2001)Blott, S.J.; Pye, K. 2001. Gradistat: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surface Processes and Landforms 26: 1237–1248. this distribution is “extremely poorly sorted” (i.e. very large range in equivalent pore diameters, SD > 16), “very fine skewed” (great excess of small equivalent pore diameters relative to a lognormal distribution, Skewness < -0.3), and “mildly leptokurtic” (slightly more peaked in the center and more tailed in the extremes than a lognormal distribution, Kurtosis = 1.11–1.50).

Figure 4
− Water retention curves and normalized pore frequency distribution curve (equation 2 and equation 5) corresponding to: (A) and (C) A horizons and (B) and (D) B horizons of the Mollisols studied. The reference curve is estimated from the five higher score horizons (black continuous dotted line).

The values of skewness and kurtosis of the curves of the four soil groups were similar to the values of the reference curve (Table 3), but as physical quality becomes poorer, the characteristic pore diameter decreases. In particular, in Groups 3 and 4, central tendency measurements are outside the reference range indicating the existence of physical quality problems in these groups’ horizons. These problems can also be inferred from Figure 4 where, especially for B horizons, in which for the same potential, soils present a higher effective saturation degree than in the reference curve. This is directly related to the higher amount of lower diameter pores and consequently, to aeration and drainage problems.

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Table 3
− Measures of the central tendency, and parameters that describe the form of the curves and the pores’ frequency distribution.

The reference curve can be also used to calculate effective saturation values at various matrix potentials (equation 2). Considering the average of five soils with higher scores of bulk density and particle density of 1.24 Mg m⁻³ and 2.55 Mg m⁻³ respectively, calculated POR_twould be 0.514 m³ m⁻³. These were the values used to calculate POR_p. For this purpose the value of effective saturation was determined at h = 10 cm which, multiplied by total porosity, was equal to 0.035 m³ m⁻³. Similarly, AC_t was determined, being 0.153 m³ m⁻³, FC 0.361 m³ m⁻³, PWP 0.136 m³ m⁻³ and PAWC 0.225 m³ m⁻³. The pore fraction, having a pore diameters lower (FC/POR_t) than 30 µm, would be 0.7 and the one higher (AC_t /POR_t) than 30-µm diameter would be 0.3. These values are within the range mentioned by other authors (Orellana and Pilatti, 2000Orellana, J.A. de; Pilatti, M.A. 2000. The ideal soil: II. Critical values of an "ideal soil", for Mollisols in the north of the Pampean region (in Argentina). Journal of Sustainable Agriculture 17: 89-109.; Pilatti et al., 2012Pilatti, M.A.; Orellana, J.A.; Imhoff, S.C.; Silva, A.P. 2012. Review of the critical limits of the optimal hydric interval. Ciencia del Suelo 30: 9-21 (in Spanish, with abstract in English).; Reynolds et al., 2002Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146.; Reynolds et al., 2009Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.) and represent useful indicators for guiding sustainable soil management.

Conclusion

Porosity in the macropore domain was low. A small decrease can, in this domain, cause severe physical restrictions in soils with a high silt percentage. Then, the capacity to rapidly drain water excesses and allow for root proliferation is not optimal due to the high silt or clay content, in A and B horizons respectively, and the low sand content which are characteristic of the matrix of the soils studied.

References

Blake, G.R.; Hartge, K.H. 1986a. Particle density. p. 377-382. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.
Blake, G.R.; Hartge, K.H. 1986b. Bulk density. p. 363-375. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/SSSA, Madison, MI, USA.
Blott, S.J.; Pye, K. 2001. Gradistat: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surface Processes and Landforms 26: 1237–1248.
Bronick, C.J.; Lal, R. 2005. Soil structure and management: a review. Geoderma 124: 3-22.
Chen, C.; Thomas, D.M.; Green, R.E.; Wagenet, R.J. 1993. Two-domain estimation of hydraulic properties in macropore soils. Soil Science Society of America Journal 57: 680-686.
Clothier, B.E.; Green, S.R.; Deurer, M. 2008. Preferential flow and transport in soil: progress and prognosis. European Journal of Soil Science 59: 2-13.
Daddow, R.L.; Warrington, G.E. 1983. Growth-limiting soil bulk densities as influenced by soil texture. USDA Forest Service, Fort Collins, CO, USA. (WSDG Report. WSDG-TN-00005).
Damiano, F.; Moschini, R.C. 2011. Least limiting water range in Argiudoll soils under Eucalyptus dunnii maiden. Ciencia del Suelo 29: 1-11 (in Spanish, with abstract in English).
Dexter, A.R.; Czyz, E.A.; Richard, G.; Reszkowska, A. 2008. A user friendly water retention function that takes account of the textural and structural pore space in soil. Geoderma 143: 243-253.
Dexter, A.R.; Czyz, E.A. 2007. Applications of S-theory in the study of soil physical degradation and its consequences. Land Degradation and Development 18: 369-381.
Dexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.
Dexter, A.R. 2004b. Soil physical quality. Part II. Friability, tillage, tilth and hard-setting. Geoderma 120: 215-225.
Dexter, A.R. 2004c. Soil physical quality. Part III: Unsaturated hydraulic conductivity and general conclusions about S-Theory. Geoderma 120: 227-239.
Gee, G.W.; Bauder, J.C. 1986. Particle size analysis. p. 383-411. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.
Genuchten, M.T. van. 1980. A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal 44: 892-898.
Genuchten, M.T. van; Simunek, J.; Leij, F.J.; Sejna, M. 2007. Code for quantifying the hydraulic functions of unsaturated soils – RETC Version 6.0. US Salinity Laboratory, Riverside. Available at: http://www.pc-progress.com/en/Default.aspx [Accessed Sep 5, 2011]
» http://www.pc-progress.com/en/Default.aspx
Ghiberto, P.J.; Pilatti, M.; Imhoff, S.; Orellana, J.A. 2007. Hydraulic conductivity of Molisolls irrigated with sodic-bicarbonated waters in Santa Fe (Argentina). Agricultural Water Management 88: 192-200.
Imhoff, S.; Ghiberto, P.J.; Grioni, A.; Gay, J.P. 2010. Porosity characterization of Argiudolls under different management systems in the flat Pampas of Argentina. Geoderma 158: 268-274.
Instituto Nacional de Tecnología Agropecuaria [INTA] 2014. GeoINTA viewer: soil maps, soil profiles and soil coverage, images and georeferenced databases = Visor GeoINTA: mapas de suelo, perfiles y coberturas de suelos, imágenes y bases de datos georeferenciadas. Available at: http://geointa.inta.gov.ar/visor2/?p=96 [Accessed Jul 11, 2014] (in Spanish).
» http://geointa.inta.gov.ar/visor2/?p=96
Jackson, M.L. 1982. Soil Chemical Analysis. = Análisis Químico de Suelos. Omega, Barcelona, Spain (in Spanish).
Kay, B.D.; Angers, D.A. 2000. Soil structure. p. A229-A276. In: Sumner, M.E., ed. Handbook of soil science. CRC Press, Boca Raton, FL, USA.
Klute, A. 1986. Water retention: laboratory methods. p. 635-660. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.
Libardi, P.L. 2005. Dynamics of Soil Water = Dinâmica da Água no Solo. EDUSP, São Paulo, SP, Brazil (in Portuguese).
Miretti, M.C.; Imhoff, S.; Silva, A.P.; Lavado, R. 2010. Soil structure degradation in patches of alfalfa fields. Scientia Agricola 67: 604-610.
Orellana, J.A. de; Pilatti, M.A. 2000. The ideal soil: II. Critical values of an "ideal soil", for Mollisols in the north of the Pampean region (in Argentina). Journal of Sustainable Agriculture 17: 89-109.
Perret, J.; Prasher, S.O.; Kantzas, A.; Langford, C. 1999. Three-dimensional quantification of macropore networks in undisturbed soil cores. Soil Science Society of America Journal 63: 1530-1543.
Pilatti, M.A.; Orellana, J.A.; Imhoff, S.C.; Silva, A.P. 2012. Review of the critical limits of the optimal hydric interval. Ciencia del Suelo 30: 9-21 (in Spanish, with abstract in English).
Pilatti, M.A.; Imhoff, S.; Ghiberto, P.J.; Marano, R.P. 2006. Changes in some physical properties of Mollisols induced by supplemental irrigation. Geoderma 133: 431-443.
Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.
Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146.
Silva, A.P.; Kay, B.D. 1997. Effect of soil water content variation on the least limiting water range. Soil Science Society of America Journal 61: 877-883.
Taboada, M.A.; Barbosa, O.A.; Cosentino, D.J. 2008. Null creation of air-filled structural pores by soil cracking and shrinkage in silty loamy soils. Soil Science 173: 130-142.
Veihmeyer, F.J.; Hendrickson, A.H. 1949. Methods of measuring field capacity and permanent wilting percentage of soils. Soil Science 68: 75-94.

Edited by

Edited by: Tairone Paiva Leão

Publication Dates

Publication in this collection
Feb 2015

History

Received
11 Feb 2014
Accepted
08 Aug 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Blake, G.R.; Hartge, K.H. 1986a. Particle density. p. 377-382. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.

[2] Blake, G.R.; Hartge, K.H. 1986b. Bulk density. p. 363-375. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/SSSA, Madison, MI, USA.

[3] Blott, S.J.; Pye, K. 2001. Gradistat: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surface Processes and Landforms 26: 1237–1248.

[4] Bronick, C.J.; Lal, R. 2005. Soil structure and management: a review. Geoderma 124: 3-22.

[5] Chen, C.; Thomas, D.M.; Green, R.E.; Wagenet, R.J. 1993. Two-domain estimation of hydraulic properties in macropore soils. Soil Science Society of America Journal 57: 680-686.

[6] Clothier, B.E.; Green, S.R.; Deurer, M. 2008. Preferential flow and transport in soil: progress and prognosis. European Journal of Soil Science 59: 2-13.

[7] Daddow, R.L.; Warrington, G.E. 1983. Growth-limiting soil bulk densities as influenced by soil texture. USDA Forest Service, Fort Collins, CO, USA. (WSDG Report. WSDG-TN-00005).

[8] Damiano, F.; Moschini, R.C. 2011. Least limiting water range in Argiudoll soils under Eucalyptus dunnii maiden. Ciencia del Suelo 29: 1-11 (in Spanish, with abstract in English).

[9] Dexter, A.R.; Czyz, E.A.; Richard, G.; Reszkowska, A. 2008. A user friendly water retention function that takes account of the textural and structural pore space in soil. Geoderma 143: 243-253.

[10] Dexter, A.R.; Czyz, E.A. 2007. Applications of S-theory in the study of soil physical degradation and its consequences. Land Degradation and Development 18: 369-381.

[11] Dexter, A.R. 2004a. Soil physical quality. Part I. Theory, effects of soil texture, density, and organic matter, and effects on root growth. Geoderma 120: 201-214.

[12] Dexter, A.R. 2004b. Soil physical quality. Part II. Friability, tillage, tilth and hard-setting. Geoderma 120: 215-225.

[13] Dexter, A.R. 2004c. Soil physical quality. Part III: Unsaturated hydraulic conductivity and general conclusions about S-Theory. Geoderma 120: 227-239.

[14] Gee, G.W.; Bauder, J.C. 1986. Particle size analysis. p. 383-411. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.

[15] Genuchten, M.T. van. 1980. A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal 44: 892-898.

[16] Genuchten, M.T. van; Simunek, J.; Leij, F.J.; Sejna, M. 2007. Code for quantifying the hydraulic functions of unsaturated soils – RETC Version 6.0. US Salinity Laboratory, Riverside. Available at: http://www.pc-progress.com/en/Default.aspx [Accessed Sep 5, 2011]
» http://www.pc-progress.com/en/Default.aspx

[17] Ghiberto, P.J.; Pilatti, M.; Imhoff, S.; Orellana, J.A. 2007. Hydraulic conductivity of Molisolls irrigated with sodic-bicarbonated waters in Santa Fe (Argentina). Agricultural Water Management 88: 192-200.

[18] Imhoff, S.; Ghiberto, P.J.; Grioni, A.; Gay, J.P. 2010. Porosity characterization of Argiudolls under different management systems in the flat Pampas of Argentina. Geoderma 158: 268-274.

[19] Instituto Nacional de Tecnología Agropecuaria [INTA] 2014. GeoINTA viewer: soil maps, soil profiles and soil coverage, images and georeferenced databases = Visor GeoINTA: mapas de suelo, perfiles y coberturas de suelos, imágenes y bases de datos georeferenciadas. Available at: http://geointa.inta.gov.ar/visor2/?p=96 [Accessed Jul 11, 2014] (in Spanish).
» http://geointa.inta.gov.ar/visor2/?p=96

[20] Jackson, M.L. 1982. Soil Chemical Analysis. = Análisis Químico de Suelos. Omega, Barcelona, Spain (in Spanish).

[21] Kay, B.D.; Angers, D.A. 2000. Soil structure. p. A229-A276. In: Sumner, M.E., ed. Handbook of soil science. CRC Press, Boca Raton, FL, USA.

[22] Klute, A. 1986. Water retention: laboratory methods. p. 635-660. In: Klute, A., ed. Methods of soil analysis. Part I. Physical and mineralogical methods. 2ed. ASA/ SSSA, Madison, MI, USA.

[23] Libardi, P.L. 2005. Dynamics of Soil Water = Dinâmica da Água no Solo. EDUSP, São Paulo, SP, Brazil (in Portuguese).

[24] Miretti, M.C.; Imhoff, S.; Silva, A.P.; Lavado, R. 2010. Soil structure degradation in patches of alfalfa fields. Scientia Agricola 67: 604-610.

[25] Orellana, J.A. de; Pilatti, M.A. 2000. The ideal soil: II. Critical values of an "ideal soil", for Mollisols in the north of the Pampean region (in Argentina). Journal of Sustainable Agriculture 17: 89-109.

[26] Perret, J.; Prasher, S.O.; Kantzas, A.; Langford, C. 1999. Three-dimensional quantification of macropore networks in undisturbed soil cores. Soil Science Society of America Journal 63: 1530-1543.

[27] Pilatti, M.A.; Orellana, J.A.; Imhoff, S.C.; Silva, A.P. 2012. Review of the critical limits of the optimal hydric interval. Ciencia del Suelo 30: 9-21 (in Spanish, with abstract in English).

[28] Pilatti, M.A.; Imhoff, S.; Ghiberto, P.J.; Marano, R.P. 2006. Changes in some physical properties of Mollisols induced by supplemental irrigation. Geoderma 133: 431-443.

[29] Reynolds, W.D.; Drury, C.F.; Tan, C.S.; Fox, C.A.; Yang, X.M. 2009. Use of indicators and pore volume-function characteristics to quantify soil physical quality. Geoderma 152: 252-263.

[30] Reynolds, W.D.; Bowman, B.T.; Drury, C.F.; Tan, C.S. 2002. Indicators of good soil physical quality: density and storage parameters. Geoderma 110: 131-146.

[31] Silva, A.P.; Kay, B.D. 1997. Effect of soil water content variation on the least limiting water range. Soil Science Society of America Journal 61: 877-883.

[32] Taboada, M.A.; Barbosa, O.A.; Cosentino, D.J. 2008. Null creation of air-filled structural pores by soil cracking and shrinkage in silty loamy soils. Soil Science 173: 130-142.

[33] Veihmeyer, F.J.; Hendrickson, A.H. 1949. Methods of measuring field capacity and permanent wilting percentage of soils. Soil Science 68: 75-94.

		OM	Sand		Silt	Clay	ρ_b
				g kg⁻¹			Mg m⁻³
A horizons	Mean	26 (27.0)	120 (123.6)		577 (21.3)	236 (23.6)	1.33 (4.7)
	Maximum	40	725		766	340	1.46
	Minimum	10	34		156	119	1.09
B horizons	Mean	13 (48.0)	109 (99.0)		509 (13.8)	337 (25.8)	1.41 (2.4)
	Maximum	31	372		634	538	1.49
	Minimum	5	26		389	224	1.35

		POR_p	AC_t		PAWC	FC/POR_t	SI	S_gi
				m³ m⁻³			%	-
A Horiz.	Mean	0.03	0.12		0.20	0.73	3.2	0.039
	Max.	0.09	0.19		0.31	0.89	10.8	0.077
	Min.	0.00	0.05		0.14	0.63	1.1	0.024
B Horiz.	Mean	0.01	0.06		0.18	0.83	1.5	0.030
	Max.	0.07	0.16		0.28	1.05	4.6	0.049
	Min.	0.00	0.02		0.12	0.65	0.5	0.021

Reference Values ^(†)		> 0.07(1)	> 0.15(1)		> 0.2(1)	0.6-0.7(1)	> 9.0(1)	> 0.05(1)
		0.07-0.04(0.5)	0.15-0.10(0.5)		0.15-0.2(0.7)		7.0-9.0(0.7)	0.035-0.05(0.7)
		< 0.04(0)	< 0.1(0)		0.1-0.15(0.3)		7.0-5.0(0.3)	0.02-0.035(0.3)
					< 0.1(0)		< 5.0(0)	< 0.02(0)

Parameter	d_median	d_mode	d_mean	SD	Skewness *	Kurtosis
		µm
Group 1: Value >70	4.6	49.3	1.5	84.9	-0.40	1.14
Group 2: Value 50-70	3.7	32.4	1.3	118.9	-0.39	1.14
Group 3: Value < 50	2.2	21.2	0.8	73.5	-0.39	1.14
Group 4: B Horizons	0.5	14.1	0.1	103.1	-0.42	1.13

Reference Range^†	3.4 – 6.8	31 – 39	1.2 – 3.0	68.7 – 145.4	-0.40 – -0.38	1.14 – 1.15

Brasil

Brasil

Soil physical quality of Mollisols quantified by a global index

Abstract

Introduction

Materials and Methods

Pore volume distribution curve

Dexter's Sgiindex

Macroporosity and Porosity of the Soil Matrix Domain

Air Capacity and Air Capacity of Soil Matrix

Plant-available water capacity

Structural stability index

Global Index of soil physical quality

Results and Discussion

Soil physical quality indicators

Water Retention Curves

Conclusion

References

Edited by

Publication Dates

History