Evaluation of Plant Models in Simulating Rice Yield under Crop Management in Rasht

Document Type : Research Article

Authors

1 Department of Agriculture, Plant production College, Gorgan University of Agricultural Sciences and Natural Resources

2 Agrotechnology Department, Faculty of Agriculture, Ferdowsi University of Mashhad

3 Department of Water Engineering, Lahijan branch, Islamic Azad University

4 Rice Research Institute of Iran, Agricultural Research, Education and Extension Organization (AREEO), Rasht

Abstract

Introduction
Nowadays, food production systems need to be explored for supplying the needs of the world's growing population, as well as sustainable production in the face of global climate change. In this regard, Cereal's yield has played a significant role in supporting global food security. The unceasing growth in demand for water in the industrial sector, drinking water, and reduction in the amount of water available for the agricultural sector has led to a reduction of water usage in rice, which threatens its production. Crops simulation models can be used to carry out various studies such as the selection of suitable cultivar and plant, determining the best agricultural management and production capacity of the area. The purpose of this study was to investigate the ORYZA2000 and AquaCrop accuracy in simulating grain and biomass yields of rice affected by irrigation and planting dates.
Materials and Methods
To evaluate the ORYZA2000 and AquaCrop models for rice production under irrigation management and planting date, a split-plot experiment based on a complete randomized block design with three replications was carried out on a local (Hashemi) cultivar in the years of 2016 and 2017 in the Rice Research Institute of Iran, Rasht. Irrigation interval was considered as the main factor at four levels including full flooding, 5, 10, and 15 days irrigation intervals, and transplanting date was assigned to subplot at three levels (April 21st, May 11th, and May 31th). Simulated and observed values of grain yield and biomass yield were evaluated based on the coefficient of determination, T-test, root mean square error (RMSE), Model efficiency (EF), Structural deviation of the model (RMD), and normalized root mean square error (NRMSE).
Results and Discussion
The results showed that normalized root mean square error of the grain yield and biomass yield were 9% and 5%, in the Aquacrop model and were 7% and 6% in the ORYZA2000 model, respectively. Evaluation of the results showed that the efficiency of the model and the coefficient of the explanation were above 0.7 and structural deviations were less than 2% that showed good accuracy in simulating the grain yield and biomass yield during calibration and validation of models. Evaluation of the amplitude of actual grain yield (3000 to 4761 kg.ha-1) and simulated by AquaCrop model (1741 to 4231 kg.ha-1) and ORYZA2000 model (with 2215 to 4766 kg.ha-1 range) showed simulated values had between -15 and 20 percent of error. The results showed that with increasing irrigation intervals, the actual grain yield decreases. The planting date of April 21st and May 11th (with an average of 3795 and 3820 kg.ha-1, respectively) had the highest yield of grain in two years, and the models also had a predicting of changes in grain yield during calibration and validation. ORYZA2000 model, due to the high coefficient of explanation and efficiency (0.83 and 0.81, respectively), has higher accuracy in simulating the grain yield than the AquaCrop model. The results showed that based on the mentioned equations, the ORYZA2000 model is well able to simulate the effect of environmental conditions including water shortage, air temperature, time, and intensity of stress during the growth cycle under the influence of irrigation and planting date on yield production. It seems that due to the better description of plant and soil conditions in the model and better genetic evaluation, it increased the accuracy of yield estimation in the ORYZA2000 model. Also, according to the acceptable results obtained in the AquaCrop model, it can be concluded that the mentioned model has a good simulation of the changes in the plant's water relations under the influence of the interaction effect of planting date and irrigation intervals.
Conclusions
According to the present study, the ORYZA2000 and Aquacrop models can be used to support the results of experiments under irrigation management conditions and planting dates.

Keywords

References

  1. Abdul-Ganiyu, S., Kyei-Baffour, N., Agyare, W. A., and Dogbe, W. 2018. Evaluating the Effect of Irrigation on Paddy Rice Yield by Applying the AquaCrop Model in Northern Ghana. In Strategies for Building Resilience against Climate and Ecosystem Changes in Sub-Saharan Africa (pp. 93-116). Springer, Singapore.
  2. Agricultural Statistics. 2017. Volume I: Crop products. 2015-16. Office of Statistics and Information -Technology, Deputy Director of Planning and Economic Affairs. Ministry of Agricultural Jihad. 90 p. (in Persian).
  3. Amiri Larijani, B., Tahmasebi, S. Z., and Nematzade, G. A. 2013. Simulation of leaf area index, biomass and grain yield of rice cultivars at different seedling ages using ORYZA2000 model. Seed and Plant Production 29: 3. 283-302.
  4. Amiri, E., and Rezaei, M. 2010. Evaluation of water–nitrogen schemes for rice in Iran, using ORYZA2000 model. Communications in Soil Science and Plant Analysis 41: 2459-2477.
  5. Amiri, E., Kavosi, M., and Kaveh, F. 2009. Evaluation of ORYZA2000, SWAP and WOFOST plant models in different irrigation management. Agricultural Engineering Research 10 (3): 13-28. (in Persian with English abstract).
  6. Amiri, E., Razavipour, T., Farid, A., and Bannayan, M. 2011. Effects of crop density and irrigation management on water productivity of rice production in Northern Iran: Field and Modeling Approach. Communications in Soil Science and Plant Analysis 42 (17): 2085-2099.
  7. Amiri, E., Rezaei, M., Rezaei, E. E., and Bannayan, M. 2014. Evaluation of Ceres-Rice, Aquacrop and Oryza 2000 models in simulation of rice yield response to different irrigation and nitrogen management strategies. Journal of Plant Nutrition 37 (11): 1749-1769.
  8. Bouman, B. A. M., and Van Laar, H. H. 2006. Description and evaluation of the rice growth model ORYZA2000 under nitrogen-limited conditions. Agricultural Systems (87): 249-273.
  9. Bouman, B. A. M., Kropff, M. J., Tuong, T. P., Wopereis, M. C. S., Ten Berge, H. F. M., and Van Laar H. H. 2001. ORYZA2000: modeling lowland rice. International Rice Research Institute, Los Banos.
  10. FAO. 2020. Food and Agricultural Organization of the United Nations (sited in: http://www,fao.org/index_en.htm/, 1/1/2020.
  11. Guo, D., Zhao, R., Xing, X., and Ma, X. 2019. Global sensitivity and uncertainty analysis of the AquaCrop model for maize under different irrigation and fertilizer management conditions. Archives of Agronomy and Soil Science 1-19.
  12. IRRI. 2013. Standard Evaluation System (SES) for Rice.
  13. Jin, X., Li, Z., Nie, C., Xu, X., Feng, H., Guo, W., and Wang, J. 2018. Parameter sensitivity analysis of the AquaCrop model based on extended fourier amplitude sensitivity under different agro-meteorological conditions and application. Field Crops Research 226: 1-15.
  14. Leng, G. 2017. Recent changes in county-level corn yield variability in the United States from observations and crop models. Science of The Total Environment 607: 683-690.
  15. Li, T., Angeles, O., Marcaida III, M., Manalo, E., Manalili, M. P., Radanielson, A., and Mohanty, S. 2017. From ORYZA2000 to ORYZA (v3): An improved simulation model for rice in drought and nitrogen-deficient environments. Agricultural and Forest Meteorology 237: 246-256.
  16. Matthews, R. B., Rivington, M., Muhammed, S., Newton, A. C., and Hallett, P. D. 2013. Adapting crops and cropping systems to future climates to ensure food security: The role of crop modelling. Global Food Security 2 (1): 24-28.
  17. Mueller, N. D., Gerber, J. S., Johnston, M., Ray, D. K., Ramankutty, N., and Foley, J. A. 2012. Closing yield gaps through nutrient and water management. Nature 490 (7419): 254-257.
  18. Nash, J. E., and Sutcliffe, J. V. 1970. River flow forecasting through conceptual models. PartI: A discussion of principles. Journal of Hydrology 10: 282-290.
  19. Neumann, K., Verburg, P. H., Stehfest, E., and Müller, C. 2010. The yield gap of global grain production: A spatial analysis. Agricultural Systems 103 (5): 316-326.
  20. Nisar, S., and Arora, V. K. 2018. Analysing Dry-Seeded Rice Responses to Planting Time and Irrigation Regimes in a Subtropical Environment Using ORYZA2000 Model. Agricultural Research 7 (4): 424-431.
  21. Pazoki, A. R. Karimi Nejad, M. and Foladi Toroghi, A. R. 2010.  Effect of planting dates on yield of ecotypes of saffron (Crocus sativus L.) in Natanz region. Crop Physiology 8 (2): 3-12. (in Persian).
  22. Raes, D., Steduto, P., Hsiao, T. C., and Fereres, E. 2012. Reference manual AquaCrop, FAO, Land and Water Division, Rome, Italy.
  23. Rinaldi, M., Losavio, N., and Flagella. Z. 2003. Evaluation of OIL CROP-SUN model for sun flower in southern Italy. Agricultural Systems 78:17-30.
  24. Rosegrant, M. W., and Cline, S. A. 2003. Global food security: challenges and policies. Science 302 (5652): 1917-1919.
  25. Tari, D. B., Amiri, E., and Daneshian, J. 2017. Simulating the Impact of Nitrogen Management on Rice Yield and Nitrogen Uptake in Irrigated Lowland by ORYZA2000 Model. Communications in Soil Science and Plant Analysis 48 (2): 201-213.
  26. Van Oort, P. A. J., Balde, A., Diagne, M., Dingkuhn, M., Manneh, B., Muller, B., Sow, A., and Stuerz, S. 2016. Intensification of an irrigated rice system in Senegal: Crop rotations, climate risks, sowing dates and varietal adaptation options. European Journal of Agronomy 80: 168-181.
  27. Wopereis, M. C. S. 1993. Quantifying the impact of soil and climate variability on rainfed rice production. PhD thesis. Wageningen (Netherlands): Wageningen Agricultural University. 188 p.
  28. Xu, J., Bai, W., Li, Y., Wang, H., Yang, S., and Wei, Z. 2019. Modeling rice development and field water balance using AquaCrop model under drying-wetting cycle condition in eastern China. Agricultural Water Management 213: 289-297.
  29. Zhai, B., Fu, Q., Li, T., Liu, D., Ji, Y., Li, M., and Cui, S. 2019. Rice Irrigation Schedule Optimization Based on the AquaCrop Model: Study of the Longtouqiao Irrigation District. Water 11 (9): 1799.
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Iranian Journal of Field Crops Research
Volume 18, Issue 4 - Serial Number 60
January 2021
Pages 401-412

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History

  • Receive Date: 06 May 2020
  • Revise Date: 12 October 2020
  • Accept Date: 02 November 2020
  • First Publish Date: 30 November 2020

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