Numerical Simulation of Soil Water Dynamics in Automated Drip Irrigated Okra Field Under Plastic Mulch

Allen, R. G., Pereira, L. S., Raes, D., and Smith, M. (1998). Crop evapotranspiration-Guidelines for computing crop water requirements-FAO Irrigation and drainage paper 56. Fao, Rome, 300(9), D05109. Search in Google Scholar

Autovino, D., Rallo, G., and Provenzano, G. (2018). Predicting soil and plant water status dynamic in olive orchards under different irrigation systems with Hydrus-2D: Model performance and scenario analysis. Agricultural water management, 203, 225-235. Search in Google Scholar

Azad, N., Behmanesh, J., Rezaverdinejad, V., Abbasi, F., and Navabian, M. (2018). Developing an optimization model in drip fertigation management to consider environmental issues and supply plant requirements. Agricultural water management, 208, 344-356. Search in Google Scholar

Cammalleri, C., Rallo, G., Agnese, C., Ciraolo, G., Minacapilli, M. and Provenzano, G. (2013). Combined use of eddy covariance and sap flow techniques for partition of ET fluxes and water stress assessment in an irrigated olive orchard. Agricultural Water Management, 120, 89-97. http://dx.doi.org/10.1016/j.agwat.2012.10.003. Search in Google Scholar

Dhawan, V. (2017). Water and agriculture in India: background paper for the South Asia expert panel during the Global Forum for Food and Agriculture (GFFA). Hamburg, OAV – German Asia-Pacific Business Association. Search in Google Scholar

Ebrahimian, H., Liaghat, A., Parsinejad, M., Playán, E., Abbasi, F., and Navabian, M. (2013). Simulation of 1D surface and 2D subsurface water flow and nitrate transport in alternate and conventional furrow fertigation. Irrigation Science, 31(3), 301-316. Search in Google Scholar

Enciso, J.M., Jifon, J., and Wiedenfeld, B. (2007). Subsurface drip irrigation of onions: effects of drip tape emitter spacing on yield and quality. Agricultural Water Management 92(3), 1-7. Search in Google Scholar

Feddes, R.A. (1982). Simulation of field water use and crop yield. In Simulation of plant growth and crop production. Pudoc, pp. 194-209. Search in Google Scholar

Ghazouani, H., Autovino, D., Rallo, G., Douh, B., and Provenzano, G. (2016). Using Hydrus-2D model to assess the optimal drip lateral depth for Eggplant crop in a sandy loam soil of central Tunisia. Italian Journal of Agrometeorology, 1, 47-58. Search in Google Scholar

Han, M., Zhao, C., Šimůnek, J., and Feng, G. (2015). Evaluating the impact of groundwater on cotton growth and root zone water balance using Hydrus-1D coupled with a crop growth model. Agricultural Water Management, 160, 64-75. Search in Google Scholar

Jones, H.G. (2004). Irrigation scheduling: advantages and pitfalls of plant-based methods. Journal of experimental botany, 55(407), 2427-2436. Search in Google Scholar

Kandelous, M. M., Šimůnek, J., Van Genuchten, M. T., and Malek, K. (2011). Soil water content distributions between two emitters of a subsurface drip irrigation system. Soil Science Society of America Journal, 75(2), 488-497. Search in Google Scholar

Kisekka, I., Migliaccio, K.W., Dukes, M.D., Schaffer, B., and Crane, J.H. (2010). Real-timeevapotranspiration- based irrigation scheduling and physiological response in a carambola (Averhoha carambola) orchard. Applied Engineering in Agriculture, 26(3), 373-380. Search in Google Scholar

Lozoya, C., Mendoza, C., Aguilar, A., Román, A., and Castelló, R. (2016). Sensor-based model driven control strategy for precision irrigation. Journal of Sensors, 9784071. Search in Google Scholar

Mailhol, J.C., Ruelle, P., Walser, S., Schütze, N., and Dejean, C. (2011). Analysis of AET and yield predictions under surface and buried drip irrigation systems using the Crop Model PILOTE and Hydrus-2D. Agricultural Water Management, 98, 1033-1044. Search in Google Scholar

Mei-Xian, L.I.U., Jing-Song, Y.A.N.G., Xiao-Ming, L.I., Mei, Y.U., and Jin, W.A.N.G. (2013). Numerical simulation of soil water dynamics in a drip irrigated cotton field under plastic mulch. Pedosphere, 23(5), 620-635. Search in Google Scholar

Minacapilli, M., Agnese, C., Blanda, F., Cammalleri, C., Ciraolo, G., D’Urso, G., Iovino, M., Pumo, D., Provenzano, G., and Rallo, G. (2009). Estimation of actual evapotranspiration of Mediterranean perennial crops by means of remote-sensing based surface energy balance models. Hydrology and Earth System Sciences, 13(7), 1061-1074. Search in Google Scholar

Mun˜oz-Carpena, R., Dukes, M.D., Li, Y., and Klassen, W. (2005). Field comparison of tensiometer and granular matrix sensor automatic drip irrigation on tomato. HortTechnology, 15 (3), 584–590. Search in Google Scholar

Radcliffe, D. E., and Simunek, J. (2018). Soil physics with HYDRUS: Modeling and applications. CRC press. Search in Google Scholar

Rallo, G., Agnese, C., Blanda, F., Minacapilli, M., and Provenzano, G. (2010). Agro- Hydrological models to schedule irrigation of Mediterranean tree crops. Italian Journal of Agrometeorology, 1, 11-21. Search in Google Scholar

Rallo, G., Agnese, C., Minacapilli, M., and Provenzano, G. (2012). Comparison of SWAP and FAO agro-hydrological models to schedule irrigation of wine grape. Journal of Irrigation and Drainage Engineering, 138(1). Search in Google Scholar

Rallo, G., González-Altozano, P., Manzano-Juárez, J., and Provenzano, G. (2017). Using field measurements and FAO-56 model to assess the eco-physiological response of citrus orchards under regulated deficit irrigation. Agricultural water management, 180, 136-147. Search in Google Scholar

Ranjbar, A., Rahimikhoob, A., Ebrahimian, H., and Varavipour, M. (2019). Simulation of nitrogen uptake and distribution under furrows and ridges during the maize growth period using HYDRUS- 2D. Irrigation Science, 37(4), 495-509. Search in Google Scholar

Richards, L.A. (1931). Capillary conduction of liquids through porous mediums. Physics, 1, 318-333. Search in Google Scholar

Ritchie, J.T. (1972). A model for predicting evaporation from a row crop with incomplete cover. Water research, 8, 1204-1213. Search in Google Scholar

Šimůnek, J., Šejna, M., and van Genuchten, M.Th. (1999). The Hydrus-2D Software Package for Simulating Two-dimensional Movement of Water, Heat, and Multiple Solutes in Variably Saturated Media. Version 2.0, IGWMC − TPS − 53. International Ground Water Modeling Center, Colorado School of Mines Golden, Colorado 251pp. Search in Google Scholar

Šimůnek, J., Šejna, M., and van Genuchten, M.Th. (2016). Recent developments and applicationsof the Hydrus computer software packages. Vadose Zone Journal, 1-25. Search in Google Scholar

Skaggs, T.H., Trout, T.J., Šimůnek, J., and Shouse, P. J. (2004). Comparison of HYDRUS-2D simulations of drip irrigation with experimental observations. Journal of irrigation and drainage engineering, 130(4), 304-310. Search in Google Scholar

Thompson, R.B., Gallardo, M., Valdez, L.C., and Fernandez, M.D. (2007). Determination of lower limits for irrigation management using in situ assessments of apparent crop water uptake made with volumetric soil water content sensors. Agricultural Water Management 92, 13-28. Search in Google Scholar

Vrugt, J. A., Hopmans, J. W., and Šimunek, J. (2001). Calibration of a two-dimensional root water uptake model. Soil Science Society of America Journal, 65(4), 1027-1037. Search in Google Scholar