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Modeling water table response to subirrigation with a buried microirrigation line source for potato production PDF

175 Pages·2000·18.2 MB·English
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Preview Modeling water table response to subirrigation with a buried microirrigation line source for potato production

MODELING WATER TABLE RESPONSE TO SUBIRRIGATION WITH A BURIED MICROIRRIGATION LINE SOURCE FOR POTATO PRODUCTION By JADIR APARECIDO ROSA A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIALFULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY UNIVERSITY OFFLORIDA 2000 to Bruna and Lucas ?vf vi..\ ACKNOWLEDGMENTS The author wishes to express his sincere appreciation to Dr. Kenneth L. Campbell for his guidance, assistance and encouragement during the last part of my course of study. Special gratitude is due to the late Prof. Allen G. Smajstria who was much more than an adviser to me. He was a brilliant scientist and an esteemed friend. I would like to express my deep admiration and respect for him in every possible way. He welcomed and helped me in adjusting to living in a different country. Without his excellent advice, guidance, patience and time, my work would not have been possible. It was a great pleasure and precious experience working with him. Special thanks are also due to the other members of my committee, Dr. D. Z. Haman, Dr. F. S. Zazueta, Dr. S. J. Locascio, and Dr. L. H. Motz for their support. The author is indebted to the Agricultural and Biological Engineering Department for the use of its facilities. Appreciation is also expressed to other graduate students, and faculty and staff members for their assistance, especially to Mr. Danny Burch for his technical assistance. Special gratitude goes to the taxpayers of Brazil, few of whom will ever read this dissertation, but all of whom have contributed to it. Thanks to CAPES, my scholarship's sponsor, and to IAPAR, my employer. Finally, behind the scenes were my loving kids, Bruna and Lucas, who rejoiced with me in good times and cheered me up in the bad. in TABLE OF CONTENTS Page ACKNOWLEDGMENTS in LIST OF TABLES vii LIST OF FIGURES viii ABSTRACT x CHAPTERS INTRODUCTION 1 1 2 REVIEW OF LITERATURE 5 Variably Saturated WaterFlow 5 Flux Density Equation: Darcy’s Law 5 Conservation ofMass: Continuity Equation 6 General Unsaturated Flow Equation: Richards Equation 7 Solutions ofthe WaterFlow Equation 9 Soil Hydraulic Properties 12 Soil Water Characteristic Curve 13 Unsaturated Hydraulic Conductivity Curve 16 Soil Water Capacity 17 Hysteresis in Soil Hydraulic Properties 18 W Root ater Uptake 20 WaterTable Management 22 Subsurface Drip Irrigation 27 MODEL DEVELOPMENT 3 30 Two-Dimensional Model Development 30 Initial Conditions 34 Boundary Conditions 34 Top Surface Boundary 34 Bottom Surface Boundary 35 Left Surface Boundary 36 Right Surface Boundary Condition 36 Seepage Surface Boundary 37 Surface Runoff 38 IV Irrigation 40 Comer Nodes 41 Time Step Update 41 Grid Size 42 Estimation of Intemode Hydraulic Conductivity 43 Evaluation ofthe Soil Hydraulic Properties 44 Water Uptake by Plant Roots 45 Solution ofthe Two-Dimensional Model 46 Mass Balance Computation 47 4 MODEL TESTING 49 Infiltration in a Large Caisson 49 Water Movement in a Cropped Soil Profile 50 Transient, Two-Dimensional, Variably Saturated WaterTable Recharge 54 Transient, Two-Dimensional, Unconfined Drainage 55 5 EXPERIMENTAL PROCEDURE 58 Subirrigation System 58 RunoffMeasurement 61 Soil Hydraulic Characteristics 62 Soil Water Retention Curve 62 Saturated Hydraulic Conductivity 64 Climate Data 66 6 NUMERICAL SOLUTION: CALIBRATION 68 Soil Hydraulic Properties 68 Estimated Daily ET 71 Deep Percolation 75 WaterTable Levels 77 Runoff 79 Irrigation 82 Water Balance 87 7 MODEL VERIFICATION AND SENSITIVITY ANALYSIS 89 Model Verification 89 Estimated Daily ET 89 WaterTable Levels 91 Irrigation 91 Runoff 96 Deep Percolation 100 Water Balance 101 Sensitivity Analysis 102 v 8 SUMMARY, CONCLUSIONS AND RECOMMENDATIONS 106 Summary 106 Conclusions 107 Recommendations forFuture Research 108 APPENDICES A MODEL ORGANIZATION 109 B NUMERICAL MODEL PROGRAM LISTING 115 LIST OF REFERENCES 153 BIOGRAPHICAL SKETCH 162 vi LIST OF TABLES 4- Table page 5- 4-1 Soil hydraulic parameters ofcrushed Bandelier Tuffused in the caisson flow . 6- example 49 4-2. Soil hydraulic parameters for the second example 51 3. Soil hydraulic parameters used in the third example 54 6- 7-1. Parameters used in van Genuchten's equation to describe the soil hydraulic properties ofPlacid Fine Sand 62 1. Parameters in van Genuchten's equation determined using original and calibrated soil water retention curves for Placid Fine Sand 69 6-2. Lengths ofthe stages and crop coefficients for potato used in this work 74 6-3. Measured and simulated runoffvolumes for three storm events in 1996 82 4. Water Balance for the 1996-simulation period 87 1. Water Balance for the 1997-simulation period 102 7-2. Sensitivity analysis ofselected parameters for the 1997 simulation period 105 A-l Input files and type ofinformation read 110 . A-2. Output files and type ofdata printed 112 A-3. List ofsignificant variables ofthe two-dimensional model 113 Vll 2- LIST OF FIGURES 3- Figure page 3- 4- 1. Schematic ofthe plant water stress response, a(h), as used by Feddes et al. (1978) 21 1. Grid system for finite difference two-dimensional model after discretizing equation (2.9). Nodes are located at the centroid ofthe cells 31 2 Finite difference grid for the field problem 39 1 Predicted water pressure head during transient infiltration in Bandelier Tuff 50 4- 4-2. Simulated pressure heads at the surface for the second example, as 5- simulated with HYDRUS and this work 52 HYDRUS 45--3. Simulated water content at selected times (days) with (symbols) and this work (lines) for the second example 52 6- 4-4. Precipitation and location ofthe water table level for the second example, as simulated with the HYDRUS and this work computer program 53 4-5. Simulation oftransient water table mounding, comparing results from this work and experimental data collected by Vauclin et al. (1979) 55 6. Simulation oftransient drainage, comparing results from this work and experimental data collected by Vauclin et al. (1975) 57 1. Layout ofthe field research experiment 59 5-2. Soil moisture curve for Placid Fine Sand 63 3. Fitted and observed soil moisture retention curves for one equivalent layer ofPlacid Fine Sand 63 1. Fitted soil moisture retention curves with original and calibrated parameters 70 6-2. Predicted hydraulic conductivity with original and calibrated parameters 71 vm 6-3. Simulated distribution ofthe daily ET over a 24-hr cycle 73 % 6-4. Crop coefficient curve for potato used in this study 74 6-5. Daily values ofpotential evapotranspiration (Penman) and crop ET for the 1996 simulated period 76 6-6. Relationship between flux and hydraulic head at the bottom ofthe soil 6- profile 78 7- 6-7. Observed and simulated water table in the 1996 growing season 80 6-8. Cumulative observed and simulated irrigation in the 1996 growing season 86 9. Simulated and observed water tables during a period ofirrigation late in the 1996 growing season 88 1. Daily values ofpotential evapotranspiration (Penman) and crop ET for the 1997 simulated period 90 7-2. Observed and simulated water table in the 1997 growing season 92 7-3. Scattergram ofobserved and simulated water table depth (taken positive downward) in the 1997 simulation 93 7-4. Cumulative observed and simulated irrigation in the 1997 growing season 94 7-5. Water table profile during irrigation in the early and mid seasons 97 7-6. Water table profile during irrigation in the early and mid hours ofthe day 97 7-7. Cumulative observed and simulated runoffin the 1997 growing season 98 7-8. Measured rainfall versus simulated and observed runoffduring the 1997 simulation period 101 IX Abstract ofDissertation Presented to the Graduate School ofthe University ofFlorida in Partial Fulfillment ofthe Requirements for the Degree ofDoctor ofPhilosophy MODELING WATER TABLE RESPONSE TO SUBIRRIGATION WITH A BURIED MICROIRRIGATION LINE SOURCE FOR POTATO PRODUCTION By Jadir Aparecido Rosa May 2000 Chairman: Kenneth L. Campbell Major Department: Agricultural and Biological Engineering In northeast Florida, the greatest use of fresh water resources is for supplemental irrigation of agricultural crops, including potato, one of the major crops in this area. Potatoes are grown on beds in soils that require irrigation even though if they are subject to naturally occurring high water tables. Most potato fields are irrigated using conventional semi-closed seepage systems that are not as efficient as most other irrigation methods. Research has shown the technical feasibility of subirrigation with a buried microirrigation system for vegetable crops in Florida, with a reduction in runoffrates and irrigation requirements as compared to the conventional semi-closed seepage irrigation system. The contribution of high water tables to soil water extracted by agricultural crops in combination with subsurface drip irrigation had not been studied accurately. Field plots were installed at the University of Florida Hastings Agricultural Research Center Yelvington Farm, and potatoes were produced during three spring growing seasons to x

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