Developments and Applications In Memoriam Eshel Bresler (1930-1991)
First Statement of Responsibility
edited by David Russo, Gedeon Dagan.
.PUBLICATION, DISTRIBUTION, ETC
Place of Publication, Distribution, etc.
Berlin, Heidelberg
Name of Publisher, Distributor, etc.
Springer Berlin Heidelberg
Date of Publication, Distribution, etc.
1993
PHYSICAL DESCRIPTION
Specific Material Designation and Extent of Item
(xxii, 306 pages 103 illustrations)
SERIES
Series Title
Advanced series in agricultural sciences, 20.
CONTENTS NOTE
Text of Note
Approaches.- 12.2.2 Non-Scaling Approaches.- 12.2.3 Inverse Modeling Approaches of Transient Flow.- 12.2.4 Outline of the Present Study.- 12.3 Simulation Experiments.- 12.3.1 Numerical Infiltration-Evaporation Experiment on 32 Bare-Soil Columns.- 12.3.2 Inverse Modeling Approach on Bare-Soil Columns.- 12.4 Validation.- 12.5 Validation of the Water Balance of Grass.- 12.6 Conclusions.- References.- 13 Impacts of Vertical Heterogeneity on Simulated Water Flow in Hawaiian Basaltic Saprolite: Relation to Recharge.- 13.1 Introduction.- 13.2 Physical Setting of Study Area.- 13.3 Methodology.- 13.3.1 Estimates of K(h) from Water Characteristic Data.- 13.3.2 Rainfall and Evaporation Data.- 13.3.3 Variability Saturated Zone Simulation Model.- 13.3.4 Hydraulic Properties and Stratigraphy of the Soil/Saprolite.- 13.3.5 Simulation Scenarios.- 13.4 Results.- 13.4.1 Time Series: Infiltration, Drainage and Water Content.- 13.4.2 Pressure Head Profiles for Extreme Periods.- 13.4.3 Profiles of Pressure Exceedence.- 13.5 Discussion.- 13.6 Conclusions.- References.- 14 Estimating Infiltration at Waste Sites: Methodology Development.- 14.1 Introduction.- 14.2 Methodology and Assumptions.- 14.2.1 Estimation of the Parameters.- 14.2.2 Calculations for Steady-State Flow.- 14.2.3 Calculations for Nonsteady Flow.- 14.3 Results.- 14.3.1 Estimating Surface Recharge Flux by Calibration with Measured Values of Saturation.- 14.3.2 Cumulative Probability of Saturation.- 14.3.3 Probability of Ponding and of Fluxes for q < R.- 14.3.4 Expected Values of Flux.- 14.3.5 Expected Values of Saturation and Flux at z = 1 m for Non Steady Infiltration.- 14.4 Summary.- References.- 15 Irrigation Scheduling Considering Soil Variability and Climatic Uncertainty: Simulation and Field Studies.- 15 Introduction.- 15.2 Theoretical Considerations.- 15.2.1 Crop Yield Model.- 15.2.2 Soil-Water Balance.- 15.2.3 Stochastic ETp Model.- 15.2.4 Mathematical Programming (Optimization).- 15.2.4.1 Irrigation Scheduling in a Homogeneous Field.- 15.2.4.2 Irrigation Scheduling in a Heterogeneous Field.- 15.3 Materials and Methods.- 15.3.1 Simulation Study.- 15.3.2 Field Study.- 15.3.3 Stochastic ETp Model for the Study Site.- 15.3.4 Irrigation Scheduling Scheme.- 15.4 Results and Discussion.- 15.4.1 Simulation Study - The Effect of Seasonal Irrigation Amount on Crop Yield.- 15.4.2 Field Experiment.- 15.4.2.1 Water Balance and Crop Yield.- 15.4.2.2 ETp Predictions.- 15.4.2.3 The Irrigation Schedule.- 15.5 Summary and Conclusions.- References.- 16 Use of Geostatistics in the Description of Salt-Affected Lands.- 16.1 Introduction.- 16.2 Geostatistical Analyses.- 16.2.1 Pseudo Cokriging.- 16.2.2 Disjunctive Kriging.- 16.3 Examples.- 16.3.1 Estimation of NO3 Using Cokriging with EC and Ca as Auxiliary Variables.- 16.3.2 Managing Soil EC in Agricultural Fields.- 16.3.2.1 The Sample Correlation Function.- 16.3.2.2 Estimation.- 16.3.2.3 Conditional Probability.- 16.4 Summary and Conclusions.- References.
Text of Note
The Contributions of Eshel Bresler to Soil Science.- List of Publications.- I Stochastic Modeling of Flow and Transport in Unsaturated Soil at Field Scale.- 1 The Bresler-Dagan Model of Flow and Transport: Recent Theoretical Developments.- 1.1 Introduction.- 1.2 The Assumptions and the Main Results of the Original BD Model.- 1.3 The Effect of Local Dispersion.- 1.4 Unsteady Flow (Infiltration and Redistribution) and Transport.- 1.5 Transport of Reactive Solutes in Heterogeneous Fields.- 1.6 Sensitivity Analysis of Crop Yield in a Heterogeneous Field.- 1.7 Solute Flux in Heterogeneous Soils.- 1.8 Mass Arrival of Sorptive Solute into the Groundwater.- 1.9 Validity of One-Dimensional Approximation for Infiltration in Heterogeneous Soils.- References.- 2 Field-Scale Solute Flux Through Macroporous Soils.- 2.1 Introduction.- 2.2 Transport Model.- 2.3 Travel Time PDF.- 2.4 Illustration of Results.- 2.5 Discussion and Conclusions.- References.- 3 Towards Pore-Scale Analysis of Preferential Flow and Chemical Transport.- 3.1 Scales of Preferential Flow.- 3.2 Immobile Water.- 3.3 Old Water - New Water.- 3.4 Subsurface Transport Investigations at Oak Ridge, Tennessee.- 3.5 Pathlength-Supply Hypothesis.- 3.6 Percolation Theory.- 3.7 Percolation Modeling.- 3.7.1 Hydraulic Conductivity and Dispersion Coefficient.- 3.7.2 Mass Transfer Coefficient.- 3.8 Stochastic Methods (Latin Hypercube Sampling).- 3.9 Synopsis.- References.- 4 Analysis of Solute Transport in Partially Saturated Heterogeneous Soils.- 4.1 Introduction.- 4.2 Basic Concepts and Definitions.- 4.3 Modeling of Solute Transport in Heterogeneous Porous Media.- 4.3.1 Transport in Saturated Porous Media.- 4.3.2 Transport in Unsaturated Porous Media.- 4.3.2.1 Simplified Stochastic Approach.- 4.3.2.2 Simulation of Solute Transport.- 4.3.2.3 General Stochastic Approach.- 4.4 Summary and Conclusions.- References.- 5 Solute Lifetime Correlations in Chemical Transport Through Field Soils.- 5.1 Introduction.- 5.2 Fundamental Statistical Concepts.- 5.3 Perfect Correlations Among Solute Lifetimes.- 5.4 Less Than Perfect Correlations Among Solute Lifetimes.- 5.5 Concluding Remarks.- References.- II Solutions of Flow and Transport in Unsaturated Media by Deterministic Models.- 6 HYSWASOR - Simulation Model of Hysteretic Water and Solute Transport in the Root Zone.- 6.1 Introduction.- 6.2 Governing Equations.- 6.2.1 Water Transport.- 6.2.2 Closed Scanning Loop Hysteresis Algorithm.- 6.2.3 Solute Transport.- 6.2.4 Root Water Uptake.- 6.3 Input.- 6.3.1 General Data.- 6.3.2 Soil Parameters.- 6.3.3 Boundary Conditions.- 6.3.4 Initial Conditions.- 6.4 Output.- 6.4.1 Screen Output.- 6.5 Simulations.- 6.5.1 Daily Irrigation.- 6.5.2 Six-Day-Interval Irrigation.- 6.6 Concluding Remarks.- References.- 7 Unstable Flow: A Potentially Significant Mechanism of Water and Solute Transport to Groundwater.- 7.1 Nature of the Problem.- 7.2 Review of Unstable Flow.- 7.3 Instability Between Fluids Differing in Density or Viscosity.- 7.4 Instability During Infiltration into Unsaturated Soils.- 7.5 Preliminary Evidence from Field Experiments.- 7.6 Final Comment.- References.- 8 Capillary Barrier at the Interface of Two Layers.- 8.1 The Particular Physical Problem Considered.- 8.2 Conditions at the Interface.- 8.3 Basic Equations.- 8.3.1 Two-Phase Flow Background and Notations.- 8.3.2 Soil Characteristics Representation.- 8.3.2.1 Capillary Pressure.- 8.3.2.2 Relative Permeability.- 8.3.2.3 Effective Capillary Drive.- 8.3.3 Propagation Velocities of Fronts.- 8.3.4 Total Velocity Expression for Particular Problem.- 8.4 System of Equations to Be Solved.- 8.5 Solution.- 8.5.1 Procedure.- 8.5.2 Result of Integration.- 8.5.3 Numerical Procedures.- 8.5.3.1 Initialization.- 8.5.3.2 Repetitive Steps.- 8.6 Applications.- 8.6.1 Values of Parameters for Reference Run.- 8.6.2 Reference Run Results.- 8.6.3 Numerical Scheme Parameter Sensitivity.- 8.6.4 Influence of Effective Capillary Drive Magnitude.- 8.6.5 Influence of Supply Rate.- 8.7 Discussion.- 8.8 Conclusions.- References.- List of Symbols.- 9 Constant-Rainfall Infiltration on Hillslopes and Slope Crests.- 9.1 Introduction.- 9.2 Constant-Rainfall Slope-Crest Infiltration: Nonlinear Formulation.- 9.2.1 Flow Equation and Conditions.- 9.2.2 Time-to-Ponding: The Two Cases.- 9.2.2.1 Case 1: R*? K1.- 9.2.2.2 Case 2: R* > K1.- 9.2.3 Remark.- 9.3 Constant-Rainfall Slope-Crest Infiltration: Linearized Formulation.- 9.3.1 Flow Equation and Conditions.- 9.3.2 Dimensional Forms.- 9.3.3 Time-to-Ponding: The Two Cases.- 9.3.4 Remark.- 9.4 Long-Slope Constant-Rainfall Infiltration: - Nonlinear Formulation.- 9.4.1 Flow Equation and Conditions.- 9.4.2 Remark.- 9.5 Long-Slope Constant-Rainfall Infiltration: Linearized Formulation.- 9.5.1 Flow Equation and Conditions, Dimensionless Forms.- 9.5.2 Solution.- 9.6 Physical Implications of Long-Slope Solutions.- 9.6.1 Distribution of Potential and Moisture Content.- 9.6.2 Standard and Rotated Flow Components.- 9.6.2.1 Horizontal and Vertical Components.- 9.6.2.2 Horizontal Inslope Flow Velocity.- 9.6.2.3 Vertical Flow Velocity.- 9.6.2.4 Downslope and Normal Components.- 9.6.3 Integrated Horizontal and Downslope Components.- 9.6.3.1 Integrated Inslope Horizontal Flow.- 9.6.3.2 Integrated Downslope Flow.- 9.6.4 Time Dependence of Surface Flow Velocity Vector.- 9.6.5 Long-Slope Time-to-Ponding.- 9.7 Constant-Rainfall Slope-Crest Solution for ? = 45.- 9.8 Physical Implications of Slope-Crest Solution.- 9.8.1 Evolution of Moisture Content and Potential Distributions.- 9.8.2 The Time Course of Surface Moisture Content.- 9.8.3 Slope-Crest Time-to-Ponding.- 9.8.4 Criterion for Validity of Long-Slope Solution.- 9.8.5 Limits on Long-Slope Solution for Arbitrary ?.- 9.9 Concluding Discussion.- 9.9.1 Inslope Horizontal Flow.- 9.9.2 Downslope Flow.- 9.9.3 The Surface Flow Velocity Vector.- 9.9.3.1 Ponded Infiltration.- 9.9.3.2 Constant-Rainfall Infiltration.- 9.9.4 Comparing the Dynamics of Ponded and Constant-Rainfall Long-Slope Infiltration.- 9.9.5 The Slope-Crest Effect.- 9.9.6 The Downslope Propagation of Ponding from a Slope-Crest.- Appendix: Properties of G(X, Y).- References.- 10 The Transport of Sorbed Chemicals in Eroded Sediment.- 10.1 Introduction.- 10.1.1 Overview of Chemical Enrichment Mechanisms.- 10.2 Sediment Transport with Rainfall Impact the Dominant Erosive Agent.- 10.2.1 Deposition.- 10.2.2 Rainfall Detachment and Redetachment.- 10.2.3 Changes in Time of Sediment Settling-Velocity Distributions During Erosion in the Presence of a Water Layer.- 10.2.4 Sediment Detachment and Transport Under Rainfall with Small Water Depth on the Soil.- 10.3 Sorbed Chemical Enrichment with a Significant Water Depth.- 10.3.1 The Effect of Erosion Process and Surface Contact Cover on the Settling-Velocity Distribution of Eroded Sediment.- 10.3.2 The Effect of Erosion Process and Surface Contact Cover on the Enrichment Ratio of Nitrogen.- 10.3.3 Theoretical Framework for Interpreting Enrichment Effects with a Significant Depth of Overland Flow.- 10.4 Sorbed Chemical Enrichment with Shallow Water Depths.- 10.4.1 Enrichment due to Differential Sorbed Chemical Concentration Within Soil Aggregates.- 10.4.2 Relationship Between Enrichment Ratio and Cumulative Loss of Eroded Sediment.- 10.5 General Discussion and Conclusions.- References.- III Experimental Techniques and Application of Statistical Methods to Field Problems.- 11 Field Measurement of Water and Solute Transport Parameters in Soils.- 11.1 The Use of Permeameters and Infiltrometers to Determine Hydraulic Properties.- 11.2 Hydraulic Properties.- 11.3 Flow Equations and Analyses.- 11.4 Results.- 11.5 Discussion.- 11.6 The Use of TDR to Determine Hydraulic and Solute Transport Properties.- 11.6.1 Hydraulic Properties.- 11.6.2 Solute Transport Parameters.- References.- 12 Estimation of Regional Effective Soil Hydraulic Parameters by Inverse Modeling.- 12.1 Introduction.- 12.2 Methods of Regionalization.- 12.2.1 Scaling
SUMMARY OR ABSTRACT
Text of Note
Water Flow and Solute Transport in Soils reflects the main trends of contemporary research in this field and its applications. The contributions fall into three main areas: - The stochastic modeling of solute transport through he- terogeneous soil in the upper layer of the unsaturated zone. - The more traditional scope of analysis of flow through homogeneous or layered formations. - The applications like new devices for field measurements, calculation of solute movement through a soil cover, and the use of geo-statistical methods to quantify solute concentrations in spatially variable soils.