Changes in Soil Water Retention Curves Due to Tillage and Natural Reconsolidation

Ahuja, L. R.; Fiedler, Fritz; Dunn, G. H.; Benjamin, Joseph G.; Garrison, Arthur W.

doi:10.2136/sssaj1998.03615995006200050011x

Cited by 152 publications

(89 citation statements)

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“…The reduction in bulk density between years when the grazing period had higher (2009 and 2011) and lower rainfall (2010 and 2012) can be explained by the rearrangement of particles promoted by cycles of soil expansion (wetting) and contraction (drying) during the cycle of the summer crop, which occurs in greater magnitude in the topsoil M. Veiga et al Table 4 -Soil bulk density and porosity in four layers of a Hapludox in four years of evaluation of two forms of sowing and four intervals between grazing of annual winter pasture DS: direct seeding; S+H: seeding + harrowing; 7D, 14D and 28D: grazing in intervals of 7, 14 and 28 days, respectively; UG: ungrazed. Means followed by different letters within each attribute and source of variation differ significantly (Tukey test, P<0.05); NS : no significant differences Attributes/ Treataments (AHUJA et al, 1998;VEIGA et al, 2008), without recompaction of the soil during the subsequent grazing cycle with lower volume of rainfall.…”

Section: --------------------------------------Kg Ha -1 -------------mentioning

confidence: 99%

“…This system results in the intensification of land use for the production of annual crops and increased and diversified the income in properties, improving the ecological and economic system (BALBINOT JUNIOR et al, 2009a;BARTH NETO et al, 2014;SALTON et al, 2013). However, the CLIS requires proper management, since the use of crop area under grazing can cause surface soil compaction due to animal trampling and reduction of soil cover by straw before the sowing of summer crop in areas managed with no-till system (NICOLOSO; LANZANOVA; LOVATO, 2006;VEIGA et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Soil physical attributes in forms of sowing the annual winter pasture and intervals between grazing

2014

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Section: --------------------------------------Kg Ha -1 -------------mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Soil physical attributes in forms of sowing the annual winter pasture and intervals between grazing

2014

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“…Consequently, our fundamental working hypothesis is that posttillage changes in pore space and hydraulic properties concern primarily the "effective pore space" within the 0-33 kPa water retention range [Ahuja et al, 1998]. …”

Section: Soil Pore Size Distributionsmentioning

confidence: 99%

“…The soil pore system is divided into textural and structural components, the latter being far more susceptible to changes due to either wetting and drying processes or external loading [Ahuja et al, 1998]. We illustrate the use of the FPE in evolution of bimodal PSD by considering an evolving interaggregate porosity (structural) and a stationary intra-aggregate porosity (textural).…”

Section: Evolution Of Pore Size Distributionmentioning

confidence: 99%

Stochastic model for posttillage soil pore space evolution

Or¹,

Leij²,

Snyder³

et al. 2000

Water Resources Research

109

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Abstract. Tillage operations disrupt surface layers of agricultural soils, creating a loosened structure with a substantial proportion of interaggregate porosity that enhances liquid and gaseous exchange properties favorable for plant growth. Unfortunately, such desirable soil tilth is structurally unstable and is susceptible to change by subsequent wetting and drying processes and other mechanical stresses that reduce total porosity and modify pore size distribution (PSD). Ability to model posttillage dynamics of soil pore space and concurrent changes in hydraulic properties is important for realistic predictions of transport processes through this surface layer. We propose a stochastic modeling framework that couples the probabilistic nature of pore space distributions with physically based soil deformation models using the Fokker-Planck equation (FPE) formalism. Three important features of soil pore space evolution are addressed: (1) reduction of the total porosity, (2) reduction of mean pore radius, and (3) changes in the variance of the PSD. The proposed framework may be used to provide input to hydrological models concerning temporal variations in near-surface soil hydraulic properties. In a preliminary investigation of this approach we link a previously proposed mechanistic model of soil aggregate coalescence to the stochastic FPE framework to determine the FPE coefficients. An illustrative example is presented which describes changes in interaggregate pore size due to wetting-drying cycles and the resulting effects on dynamics of the soil water characteristic curve and hydraulic conductivity functions. IntroductionThe tilled "plow layer" of agricultural soils plays a crucial role in determining crop productivity and transport of gas, The primary objective of this study was to develop a framework for modeling posttillage evolution of soil PSD based on coupling of stochastic formulation with physically based process models. We propose the use of the forward Kolmogorov 1641

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“…The sampling process itself often causes the most severe disturbance, when an "undisturbed" soil sample is isolated from the natural embedding. (ii) Soils exhibit considerable temporal variability (Mapa et al, 1986;Ahuja et al, 1998;Leij et al, 2002). Thus, measurements at the same site may yield different results if applied at different times (van Es et al, 1999).…”

Section: The Challenge Of Determining Soil Hydraulic Propertiesmentioning

confidence: 99%

Determining Soil Hydraulic Properties

Durner

Lipsius

2005

Encyclopedia of Hydrological Sciences

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Hydraulic properties are required for modeling water and solute transport in unsaturated soils. The bottleneck for the successful application of numerical simulation models lays usually in their parameter estimation requirements. Methods to determine hydraulic properties can be classified into indirect and direct approaches. Indirect methods encompass the estimation of hydraulic properties by pedotransfer functions from more easily measured soil properties, and the prediction of the unsaturated hydraulic conductivity function from the water retention curve ( WRC ). In direct methods, observations of flow attributes from laboratory or field experiments are evaluated. This article reviews common methods to estimate the hydraulic conductivity function from the water retention characteristic and various direct measurement techniques in the laboratory and the field. We conclude with an outlook on contemporary developments in measurement techniques, stressing the key role of inverse modeling of experiments to derive optimum hydraulic properties and the importance of a future combination of noninvasive measurement techniques with inverse modeling by stochastic data fusion.

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Changes in Soil Water Retention Curves Due to Tillage and Natural Reconsolidation

Cited by 152 publications

References 0 publications

Soil physical attributes in forms of sowing the annual winter pasture and intervals between grazing

Soil physical attributes in forms of sowing the annual winter pasture and intervals between grazing

Stochastic model for posttillage soil pore space evolution

Determining Soil Hydraulic Properties

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