Simulation of maize evapotranspiration: An inter-comparison among 29 maize models

[en] Crop yield can be affected by crop water use and vice versa, so when trying to simulate one or the other, it can be important that both are simulated well. In a prior inter-comparison among maize growth models, evapotranspiration (ET) predictions varied widely, but no observations of actual ET were available for comparison. Therefore, this follow-up study was initiated under the umbrella of AgMIP (Agricultural Model Inter-Comparison and Improvement Project). Observations of daily ET using the eddy covariance technique from an 8-year-long (2006–2013) experiment conducted at Ames, IA were used as the standard for comparison among models. Simulation results from 29 models are reported herein. In the first “blind” phase for which only weather, soils, phenology, and management information were provided to the modelers, estimates of seasonal ET varied from about 200 to about 700 mm. Subsequent three phases provided (1) leaf area indices for all years, (2) all daily ET and agronomic data for a typical year (2011), and (3) all data for all years, thus allowing the modelers to progressively calibrate their models as more information was provided, but the range among ET estimates still varied by a factor of two or more. Much of the variability among the models was due to differing estimates of potential evapotranspiration, which suggests an avenue for substantial model improvement. Nevertheless, the ensemble median values were generally close to the observations, and the medians were best (had the lowest mean squared deviations from observations, MSD) for several ET categories for inter-comparison, but not all. Further, the medians were best when considering both ET and agronomic parameters together. The best six models with the lowest MSDs were identified for several ET and agronomic categories, and they proved to vary widely in complexity in spite of having similar prediction accuracies. At the same time, other models with apparently similar approaches were not as accurate. The models that are widely used tended to perform better, leading us speculate that a larger number of users testing these models over a wider range of conditions likely has led to improvement. User experience and skill at calibration and dealing with missing input data likely were also a factor in determining the accuracy of model predictions. In several cases different versions of a model within the same family of models were run, and these within-family inter-comparisons identified particular approaches that were better while other factors were held constant. Thus, improvement is needed in many of the models with regard to their ability to simulate ET over a wide range of conditions, and several aspects for progress have been identified, especially in their simulation of potential ET. © 2019

Disciplines :

Agriculture & agronomy
Computer science

Author, co-author :

Kimball, B. A.; U.S. Arid-Land Agricultural Research Center, USDA-ARS, Maricopa, AZ 85138, United States

Boote, K. J.; University of Florida, Agronomy Department, Gainesville, FL 32611, United States

Hatfield, J. L.; National Laboratory for Agriculture and the Environment, USDA-ARS, Ames, IA 50010-3120, United States

Ahuja, L. R.; Agricultural Systems Research Unit, USDA, Agricultural Research Service, 2150 Centre Avenue, Bldg. D., Suite 200, Ft. Collins, CO 80526, United States

Stockle, C.; Biological Systems Engineering, Washington State University, 1935 E. Grimes Way, P.O. Box 646120, Pullman, WA 99164-6120, United States

Archontoulis, S.; Iowa State University, Department of Agronomy, Ames, IA 50010, United States

Baron, C.; CIRAD, UMR TETIS, Montpellier, F-34398, France, TETIS, University Montpellier, AgroParisTech, CIRAD, CNRS, IRSTEA, Montpellier, France

Basso, B.; Michigan State University, Department Geological Sciences and W.K. Kellogg Biological Station, 288 Farm Ln, 307 Natural Science Bldg., East Lansing, MI 48824, United States

Bertuzzi, P.; US1116 AgroClim, INRA centre de recherche Provence-Alpes-Côte d'Azur, 228, route de l'Aérodrome, CS 40 509, Domaine Saint Paul, Site Agroparc, Cedex 9, Avignon, 84914, France

Constantin, J.; AGIR, Université de Toulouse, INRA, INPT, INP- EI PURPAN, 24 Chemin de Borde Rouge - Auzeville CS 52627, CastanetTolosan, France

More authors (25 more)

Language :

English

Title :

Simulation of maize evapotranspiration: An inter-comparison among 29 maize models

Publication date :

2019

Journal title :

Agricultural and Forest Meteorology

ISSN :

0168-1923

eISSN :

1873-2240

Publisher :

Elsevier B.V.

Volume :

271

Pages :

264-284

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 25 April 2019

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Allen, R.G., Pereira, L.S., Raes, D., Smith, M., Crop Evapotranspiration: Guidelines for Computing Crop Water Requirements, FAO Irrigation and Drainage Paper 56. 1998, Food and Agriculture Organization of the United Nations, Rome, Italy.
Allen, R.G., Walter, I.A., Elliott, R., Howell, T., Itenfisu, D., Jensen, M., The ASCE Standardized Reference Evapotranspiration Equation. 2005, American Society of Civil Engineers, Reston, Virginia, 195.
Asseng, S., Ewert, F., Rosenzweig, C., Jones, J.W., Hatfield, J.L., Ruane, A.C., Boote, K.J., Thorburn, P.J., Rötter, R.P., Cammarano, D., Brisson, N., Basso, B., Martre, P., Aggarwal, P.K., Angulo, C., Bertuzzi, P., Biernath, C., Challinor, A.J., Doltra, J., Gayler, S., Goldberg, R., Grant, R., Heng, L., Hooker, L., Hunt, L.A., Ingwersen, J., Izaurralde, R.C., Kersebaum, K.C., Müller, C., Naresh Kumar, S., Nendel, C., O'Leary, G., Olesen, J.E., Osborne, T.M., Palosuo, T., Priesack, E., Ripoche, D., Semenov, M.A., Shcherbak, I., Steduto, P., Stöckle, C., Stratonovitch, P., Streck, T., Supit, I., Tao, F., Travasso, M., Waha, M.K., Wallach, D., White, J.W., Williams, J.R., Wolf, J., Uncertainties in simulating wheat yields under climate change. Nat. Clim. Change 3 (2013), 827–832.
Asseng, S., Ewert, F., Martre, P., Rotter, R.P., Lobell, D.B., Cammarano, D., Kimball, B.A., Ottman, M.J., Wall, G.W., White, J.W., Reynolds, M.P., Alderman, P.D., Prasad, P.V.V., Aggarwal, P.K., Anothai, J., Basso, B., Biernath, C., Challinor, A.J., De Sanctis, G., Doltra, J., Fereres, E., Garcia-Vila, M., Gayler, S., Hoogenboom, G., Hunt, L.A., Izaurralde, R.C., Jabloun, M., Jones, C.D., Kersebaum, K.C., Koehler, A.K., Muller, C., Naresh Kumar, S., Nendel, C., O'Leary, G., Olesen, J.E., Palosuo, T., Priesack, E., Eyshi Rezaei, E., Ruane, A.C., Semenov, M.A., Shcherbak, I., Stockle, C., Stratonovitch, P., Streck, T., Supit, I., Tao, F., Thorburn, P.J., Waha, K., Wang, E., Wallach, D., Wolf, J., Zhao, Z., Zhu, Y., Rising temperatures reduce global wheat production. Nat. Clim. Change 5 (2015), 143–147.
Bassu, S., Brisson, N., Durand, J.-L., Boote, K., Lizaso, J., Jones, J.W., Rosenzweig, C., Ruane, A.C., Adam, M., Baron, C., Basso, B., Biernath, C., Boogaard, H., Conijn, S., Corbeels, M., Deryng, D., DeSanctis, G., Gayler, S., Grassini, P., Hatfield, J., Hoek, S., Izaurralde, C., Jongschaap, R., Kemanian, A.R., Kersebaum, K.C., Kim, S.-H., Kumar, N.S., Makowski, D., Mueller, C., Nendel, C., Priesack, E., Pravia, M.V., Sau, F., Shcherbak, I., Tao, F., Teixeira, E., Timlin, D., Waha, K., How do various maize crop models vary in their responses to climate change factors?. Glob. Change Biol. 20 (2014), 2301–2320, 10.1111/gcb.12520.
Boote, K.J., Sau, F., Hoogenboom, G., Jones, J.W., Experience with water balance, evapotranspiration, and prediction of water stress effects in the CROPGRO model. Ahuja, L.R., Reddy, V.R., Saseendran, S.A., Yu, Q., (eds.) Response of Crops to Limited Water: Modeling Water Stress Effects on Plant Growth Processes, Volume 1 of Advances in Agricultural Systems Modeling, 2008, ASA-CSSA-SSSA, Madison, WI, 59–103.
Brisson, N., Seguin, B., Bertuzzi, P., Agrometeorological soil water balance for crop simulation models. Agric. For. Meteorol. 59 (1992), 267–287.
Brisson, N., Itier, B., L'Hotel, J.C., Lorendeau, J.Y., Parameterisation of the Shuttleworth-Wallace model to estimate daily maximum transpiration for use in crop models. Ecol. Model. 107 (1998), 159–169.
Brisson, N., Gary, C., Justes, E., Roche, R., Mary, B., Ripoche, D., Zimmer, D., Sierra, J., Bertuzzi, P., Burger, P., Bussière, F., Cabidoche, Y.M., Cellier, P., Debaeke, P., Gaudillère, J.P., Hènault, C., Maraux, F., Sequin, B., Sinoquet, H., An overview of crop model STICS. Eur. J. Agron. 18 (2003), 309–332.
Cammarano, D., Rötter, R.P., Asseng, S., Ewert, F., Wallach, W., Martre, P., Hatfield, J.L., Jones, J.W., Rosenzweig, C., Ruane, A.C., Boote, K.J., Thorburn, P.J., Kersebaum, K.C., Aggarwal, P.K., Angulo, C., Basso, B., Bertuzzi, P., Biernath, C., Brisson, N., Challinor, A.J., Doltra, J., Gayler, S., Goldberg, R., Heng, L., Hooker, J.E., Hunt, L.A., Ingwersen, J., Izaurraldez, R.C., Müller, C., Kumar, S.N., Nendel, C., O'Leary, G., Olesen, J.E., Osborne, T.M., Priesack, E., Ripoche, D., Steduto, P., Stöckle, C.O., Stratonovitch, P., Streck, T., Supit, I., Tao, F., Travasso, M., Waha, K., White, J.W., Wolf, J., Uncertainty of wheat water use: simulated patterns and sensitivity to temperature and CO 2 . Field Crops Res. 198 (2016), 80–92, 10.1016/j.fcr.2016.08.015.
Campbell, G.S., Soil Physics With BASIC. 1985, Elsevier, New York, New York, 150.
DeJonge, K.C., Thorp, K.R., Standardized reference evapotranspiration and dual crop coefficient approach in the DSSAT Cropping System Model. Trans. ASABE 60:6 (2017), 1965–1981.
Dold, C., Büyükcangaz, H., Rondinelli, W., Prueger, J.H., Sauer, T.J., Hatfield, J.L., Long-term carbon uptake of agro-ecosystems in the Midwest. Agric. For. Meteorol. 232 (2016), 128–140.
Doorenbos, J., Pruitt, W.O., Guidelines for Predicting Crop Water Requirements. FAO Irrig. And Drain. Paper 24. 1985, FAO, Rome.
Durand, J.L., Delusca, K., Boote, K.J., Lizaso, J., Manderscheid, R., Weigel, H.J., Ruane, A.C., Rosenzweig, C., Ahuja, L., Anapalli, S., Basso, B., Baron, C., Bertuzzi, P., Deryng, D., Ewert, F., Gaiser, T., Gayler, S., Heinlein, F., Kersebaum, F.C., Kim, S.H., Muller, C., Nendel, C., Olioso, A., Priesack, E., Villegas, J.R., Ripoche, D., Seidel, S.I., Srivastava, A., Tao, F., Timlin, D., Twine, T., Wang, E., Webber, H., Zhao, Z., How accurately do maize crop models simulate the interactions of atmospheric CO2 concentration levels with limited water supply on water use and yield?. Eur. J. Agron. 100 (2018), 67–75.
Fan, Y., Li, H., Miguez-Macho, G., Global patterns of groundwater table depth. Science 339 (2013), 940–943.
Fleisher, D.H., Condori, B., Quiroz, R., Alva, A., Asseng, S., Barreda, C., Bindi, M., Boote, K.J., Ferrise, R., Franke, A.C., Govindakrishnan, P.M., Harahagazwe, D., Hoogenboom, G., Naresh Kumar, S., Merante, P., Nendel, C., Olesen, J.E., Parker, P.S., Raes, D., Raymundo, R., Ruane, A.C., Stockle, C., Supit, I., Vanuytrecht, E., Wolf, J., Woli, P., A potato model intercomparison across varying climates and productivity levels. Glob. Change Biol. Bioenergy 23 (2017), 1258–1281.
Gauch, H.G., Hwang, J.T.G., Fick, G.W., Model evaluation by comparison of model-based predictions and measured values. Agron. J. 95 (2003), 1442–1446.
Goudriaan, J., Crop Micrometerology: A Simulation Study. Simulation Monographs. 1977, PUDOC, Wageningen, the Netherlands.
Goudriaan, J., Van Laar, H.H., Radiation in crops. Goudriaan, J., Van Laar, H.H., (eds.) Modelling Potential Crop Growth Processes. Textbook With Exercises, 1994, Kluwer Academic Publ., Dordrecht, The Netherlands, 378–399.
Hamon, W.R., Computation of direct runoff amounts from storm rainfall. Int. Assoc. Sci. Hydrol. Publ. 63 (1963), 52–62.
Hargreaves, G.H., Moisture availability and crop production. Trans. ASAE 18 (1975), 980–984.
Hasegawa, T., Lai, T., Yin, X., Zhu, Y., Boote, K., Baker, J., Bregaglio, S., Buis, S., Confalonieri, R., Fugice, J., Fumoto, T., Gaydon, D., Naresh Kumar, S., Lafarge, T., Marcaida, M., Masutomi, Y., Nakagawa, H., Oriol, P., Ruget, F., Singh, U., Tang, L., Tao, F., Wakatsuki, H., Wallach, D., Wang, Y., Wilson, L.T., Yang, L., Yang, Y., Yoshida, H., Zhang, Z., Zhu, J., Causes of variation among rice models in yield response to CO 2 examined with free-air CO 2 enrichment and growth chamber experiments. Sci. Rep., 7, 2017, 14858, 10.1038/s41598-017-13582-y.
Hernandez-Ramirez, G., Hatfield, G.L., Prueger, J.H., Sauer, T.J., Energy balance and turbulent flux partitioning in a corn-soybean rotation in the Midwestern U.S. Theor. Appl. Climatol. 100 (2010), 79–92.
Huth, N.I., Bristow, K.L., Verburg, K., Swim3. Trans. ASABE 55 (2012), 1303–1313.
Hutson, J.L., Wagenet, R.J., LEACHM: Leaching Estimation and Chemistry Model: A Process-Based Model of Water and Solute Movement, Transformations, Plant Uptake and Chemical Reactions in the Unsaturated Zone. Version 3.0. Research Series No. 93-3. 1992, Cornell University, Ithaca, N. Y.
Idso, S.B., Non-water-stressed baselines: a key to measuring and interpreting plant water stress. Agric. Meteorol. 27 (1982), 59–70.
Johnsson, H., Bergström, H.L., Jansson, P.E., Paustian, K., Simulated nitrogen dynamics and losses in a layered agricultural soil. Agric. Ecosyst. Environ. 18 (1987), 333–356.
Kim, S.-H., Yang, Y., Timlin, D.J., Fleisher, D., Dathe, A., Reddy, V.R., Modeling nonlinear temperature responses of leaf growth, development, and biomass in MAIZSIM. Agron. J. 104 (2012), 1523–1537.
Kimball, B.A., White, J.W., Wall, G.W., Ottman, M.J., Infrared-warmed and un-warmed wheat vegetation indices coalesce using canopy-temperature-based growing degree days. Agron. J. 104 (2012), 114–118.
Li, T., Hasegawa, T., Yin, X., Zhu, Y., Boote, K., Adam, M., Bregaglio, S., Buis, S., Confalonieri, R., Fumoto, T., Gaydon, D., Marcaida, M. III, Nakagawa, H., Oriol, P., Ruane, A.C., Ruget, F., Singh, B., Singh, U., Tang, L., Tao, F., Wilkens, P., Yoshida, H., Zhang, Z., Bouman, B., Uncertainties in predicting rice yield by current crop models under a wide range of climatic conditions. Glob. Change Biol. 21 (2015), 1328–1341.
Logsdon, S.D., Hernandez-Ramirez, G., Hatfield, J.L., Sauer, T.J., Prueger, J.H., Schilling, K.E., Soil water and shallow groundwater relations in an agricultural hillslope. Soil Sci. Soc. Am. J. 73 (2009), 1461–1468.
Maiorano, A.P., Martre, P., Asseng, S., Ewert, F., Müller, C., Rötter, R.P., Ruane, A.C., Seminov, M.A., Wallach, D., Wang, E., Alderman, P.D., Kassie, B.T., Biernath, C., Basso, B., Cammarano, D., Challinor, A.J., Doltra, J., Dumont, B., Rezaei, E.E., Gayler, S., Kersebaum, K.C., Kimball, B.A., Koehler, A.-K., Liu, B., O'Leary, G.J., Olesen, J.E., Ottman, M.J., Priesach, E., Reynolds, M., Stratonovitch, P., Streck, T., Thorburn, P.J., Waha, K., Wall, G.W., White, J.W., Zhao, Z., Zhu, Y., Crop model improvement reduces the uncertainty to temperature of multi-model ensembles. Field Crops Res. 202 (2017), 5–20.
Monteith, J.L., Evaporation and environment. 19th Symposia of the Society for Experimental Biology, vol. 19, 1965, University Press, Cambridge, 205–234.
Nimah, M., Hanks, R.J., Model for estimating soil-water-plant-atmospheric interrelation: I. Description and sensitivity. Soil Sci. Soc. Am. Proc. 37 (1973), 522–527.
Ordóñez, R.A., Castellano, M.J., Hatfield, J.L., Helmers, M.J., Licht, M.A., Liebman, M., Dietzel, R., Martinez-Feria, R., Iqbal, J., Puntel, L.A., Córdova, S.C., Togliatti, K., Wright, E.E., Archontoulis, S.V., Maize and soybean root front velocity and maximum depth in Iowa, USA. Field Crops Res. 215 (2018), 122–131.
Pickering, N.B., Jones, J.W., Boote, K.J., Adapting SOYGRO V5.42 for prediction under climate change conditions. Rosenzweig, C., Jones, J.W., Allen, L.H. Jr., (eds.) Climate Change and Agriculture: Analysis of Potential International Impacts, ASA Spec. Pub. No. 59, 1995, ASA-CSSA-SSSA, Madison, WI, 77–98.
Priestly, C.H.B., Taylor, R.J., On the assessment of surface heat flux and evaporation using large-scale parameters. Mon. Weather Rev. 100 (1972), 81–92.
Probert, M.E.E., Dimes, J.P.P., Keating, B.A.A., Dalal, R.C.C., Strong, W.M.M., APSIM's water and nitrogen modules and simulation of the dynamics of water and nitrogen in fallow systems. Agric. Syst. 56 (1998), 1–28, 10.1016/S0308-521X(97)00028-0.
Rippey, B.R., The U.S. drought of 2012. Weather Clim. Extreme 10 (2015), 57–64.
Ritchie, J.T., Model for predicting evaporation from a row crop with incomplete cover. Water Resour. Res. 8 (1972), 1204–1213.
Ritchie, J.T., Godwin, D.C., Otter-Nache, S., CERES-Wheat: A Simulation Model of Wheat Growth and Development. 1988, Texas A&M University Press, College Station, TX.
Ritchie, J.T., Porter, C.H., Judge, J., Jones, J.W., Suleiman, A.A., Extension of an existing model for soil water evaporation and redistribution under high water content conditions. Soil Sci. Soc. Am. J. 73 (2009), 792–801.
Rizzo, G., Edreira, J.I.R., Archontoulis, S.V., Yang, H.S., Grassini, P., Do shallow water tables contribute to high and stable maize yields in the US Corn Belt?. Glob. Food Sec. 18 (2018), 27–34.
Sauer, T.J., Methods of soil analysis—Part 1, physical and mineralogical methods. Dane, J.D., Topp, G.C., (eds.) Heat flux density, 2002, American Society of Agronomy, Madison, WI, 1233–1248.
Sau, F., Boote, K.J., Bostick, W.M., Jones, J.W., Minguez, M.I., Testing and improving evapotranspiration and soil water balance of the DSSAT crop models. Agron. J. 96 (2004), 1243–1257.
Seidel, S.J., Palosuo, T., Thorburn, P., Wallach, D., Towards improved calibration of models—where are we now and where should we go?. Eur. J. Agron. 94 (2018), 25–35, 10.1016/j.eja.2018.01.006.
Shuttleworth, W.J., Wallace, J.S., Evaporation from sparse crops—an energy combination theory. Q. J. R. Meteorol. Soc. 111 (1985), 839–855.
Simunek, J., Huang, K., van Genuchten, M., The HYDRUS Code for Simulating the One-Dimensional Movement of Water, Heat, and Multiple Solutes in Variably-saturated Media, Version 6.0. 1998, Tech. Rep. 144, U.S. Salinity Lab., United States Dep. of Agriculture, Agricultural Research Service.
Soufizadeh, S., Munaro, E., McLean, G., Massignam, A., van Oosterom, E.J., Chapman, S.C., Messina, C., Cooper, M., Hammer, G.L., Modeling the nitrogen dynamics of maize crops-enhancing the APSIM maize model. Eur. J. Agron. 100 (2018), 118–131.
Suleiman, A.A., Ritchie, J.T., Modeling soil water redistribution during second-stage evaporation. Soil Sci. Soc. Am. J. 67 (2003), 377–386.
Tanner, C.B., Sinclair, T.R., Efficient water use in crop production: research or research?. Taylor, H.M., Jordan, W.R., Sinclair, T.R., (eds.) Limitations to Efficient Water Use in Crop Production, 1983, American Society of Agronomy, Madison, WI, USA, 1–27.
Tao, F., Yokozawa, M., Zhang, Z., Modelling the impacts of weather and climate variability on crop productivity over a large area: a new process-based model development, optimization, and uncertainties analysis. Agric. For. Meteorol. 149 (2009), 831–850.
Timlin, D.J., Pachepsky, Ya., Acock, B.A., Šimunek, J., Flerchinger, G., Whisler, F., Error analysis of soil temperature simulations using measured and estimated hourly weather data with 2DSOIL. Agric. Sys. 72 (2002), 215–239.
Twine, T.E., Bryant, J.J., Richter, K.T., Bernacchi, C.J., Mcconnaughay, K.D., Morris, S.J., Leakey, A.D.B., Impacts of elevated CO 2 concentration on the productivity and surface energy budget of the soybean and maize agroecosystem in the Midwest USA. Glob. Change Biol. 19 (2013), 2838–2852, 10.1111/gcb.12270.
Villalobos, F.J., Fereres, E., Evaporation measurements beneath corn, cotton, and sunflower canopies. Agron. J. 82 (1990), 1152–1159 3-2.
Wang, E., Martre, P., Ewert, F., Zhao, Z., Maiorano, A., Rötter, R.P., Kimball, B.A., Ottman, M.J., Wall, G.W., White, J.W., Reynolds, M.P., Alderman, P.D., Aggarwal, P.K., Anothai, J., Basso, B., Biernath Cammarano, D., Challinor, A.J., De Sanctis, G., Doltra, J., Fereres, E., Garcia-Vila, M., Gayler, S., Hoogenboom, G., Hunt, L.A., Izaurralde, R.C., Jabloun, M., Jones, C.D., Kersebaum, K.C., Koehler, A.-K., Müller, C., Liu, L., Kumar, S.N., Nendel, C., O'Leary, G., Olesen, J.E., Palosuo, T., Priesack, E., Rezaei, E.E., Ripoche, D., Ruane, A.C., Semenov, M.A., Shcherbak, I., Stöckle, C., Stratonovitch, P., Streck, T., Supit, I., Tao, F., Thorburn, P., Waha, K., Wallach, D., Wang, Z., Wolf, J., Zhu, Y., Asseng, S., The uncertainty of crop yield projections is reduced by improved temperature response functions. Nat. Plants 3:1702 (2017), 1–11, 10.1038/nplants.2017.102.
Webb, E.K., Pearman, G.I., Leuning, R., Correction of flux measurements for density effects due to heat and water vapour transfer. Q.J.R. Meteorol Soc. 106 (1980), 85–100.
Webber, H., Ewert, F., Kimball, B.A., Siebert, S., White, J.W., Wall, G.W., Ottman, M.J., Trawally, D.N.A., Gaiser, T., Simulating canopy temperature for modelling heat stress in cereals. Environ. Model. Softw. 77 (2016), 143–155, 10.1016/j.envsoft.2015.12.003.
Yang, Y., Kim, S.-H., Timlin, D.J., Fleisher, D.H., Quebedeaux, B., Reddy, V.R., Simulating canopy evapotranspiration and photosynthesis of corn plants under different water status using a coupled MaizeSim+2DSOIL model. Trans. ASAEB 52:3 (2009), 1011–1024.
Yin, X., van Laar, H.H., Crop Systems Dynamics: An Ecophysiological Simulation Model for Genotype-By-Environment Interactions. 2005, Wageningen Academic Publishers.