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Simulation of genotype-by-environment interactions on irrigated soybean yields in the U.S. Midsouth

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  • Salmerόn, Montserrat
  • Purcell, Larry C.
  • Vories, Earl D.
  • Shannon, Grover

Abstract

Dynamic crop models that incorporate the effect of environmental variables can potentially explain yield differences associated with location, year, planting date, and cultivars with different growing cycles. Soybean (Glycine max (L.) Mer.) cultivar coefficients for the DSSAT-CROPGRO model were calibrated from two growing seasons (2012−2013) comprising 58 irrigated environments (site×year×planting date combinations) for cultivars within maturity groups (MGs) 3 to 6 using end of season data (yield, seed weight, and seed oil and protein concentration) and previously calibrated phenology coefficients. Model accuracy after calibration of cultivar coefficients by MG (cultivars averaged within a MG) was similar compared to cultivar-specific coefficients. During the subsequent growing season in 2014 (33 environments), the model efficiency (ME) for predicting yield was 0.40, with a root mean square error (RMSE) of 571kgha−1. The model was less efficient predicting seed number and seed weight (ME=0.06 and −0.06, respectively) than yield. The model was able to simulate differences in seed oil concentration across environments and MGs (ME=0.52), but not protein concentration (ME=−0.25). The analysis of yield stability had similar slopes for the observed and predicted yield regressions against an observed environmental index (EI) that were only dependent on the MG. Simulated yields were significantly different from the observed when EI>0, but yield differences in the highest yielding environments were still relatively small (245 to 608kgha−1). The results indicate an overall robust model performance in capturing G×E responses with coefficients calibrated by MG.

Suggested Citation

  • Salmerόn, Montserrat & Purcell, Larry C. & Vories, Earl D. & Shannon, Grover, 2017. "Simulation of genotype-by-environment interactions on irrigated soybean yields in the U.S. Midsouth," Agricultural Systems, Elsevier, vol. 150(C), pages 120-129.
    • Handle: RePEc:eee:agisys:v:150:y:2017:i:c:p:120-129
    DOI: 10.1016/j.agsy.2016.10.008
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    1. Boote, K. J. & Kropff, M. J. & Bindraban, P. S., 2001. "Physiology and modelling of traits in crop plants: implications for genetic improvement," Agricultural Systems, Elsevier, vol. 70(2-3), pages 395-420.
    2. Salmerón, Montserrat & Purcell, Larry C., 2016. "Simplifying the prediction of phenology with the DSSAT-CROPGRO-soybean model based on relative maturity group and determinacy," Agricultural Systems, Elsevier, vol. 148(C), pages 178-187.
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    1. Montero Bulacio, Enrique & Romagnoli, Martín & Otegui, María E. & Chan, Raquel L. & Portapila, Margarita, 2023. "OSTRICH-CROPGRO multi-objective optimization methodology for calibration of the growing dynamics of a second-generation transgenic soybean tolerant to high temperatures and dry growing conditions," Agricultural Systems, Elsevier, vol. 205(C).

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