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Predicting maize phenology: intercomparison of functions for developmental response to temperature
Resumen
Accurate prediction of phenological development in maize (Zea mays L.) is fundamental to determining crop adaptation and yield potential. A number of thermal functions are used in crop models, but their relative precision in predicting maize development has not been quantified. The objectives of this study were (i) to evaluate the precision of eight thermal functions, (ii) to assess the effects of source data on the ability to differentiate among thermal
[ver mas...]
Accurate prediction of phenological development in maize (Zea mays L.) is fundamental to determining crop adaptation and yield potential. A number of thermal functions are used in crop models, but their relative precision in predicting maize development has not been quantified. The objectives of this study were (i) to evaluate the precision of eight thermal functions, (ii) to assess the effects of source data on the ability to differentiate among thermal functions, and (iii) to attribute the precision of thermal functions to their response across various temperature ranges. Data sets used in this study represent >1000 distinct maize hybrids, >50 geographic locations, and multiple planting dates and years. Thermal functions and calendar days were evaluated and grouped based on their temperature response and derivation as empirical linear, empirical nonlinear, and process-based functions. Precision in predicting phase durations from planting to anthesis or silking and from silking to physiological maturity was evaluated. Large data sets enabled increased differentiation of thermal functions, even when smaller data sets contained orthogonal, multi-location and -year data. At the highest level of differentiation, precision of thermal functions was in the order calendar days < empirical linear < process based < empirical nonlinear. Precision was associated with relatively low temperature sensitivity across the 10 to 26°C range. In contrast to other thermal functions, process-based functions were derived using supra-optimal temperatures, and consequently, they may better represent the developmental response of maize to supra-optimal temperatures. Supra-optimal temperatures could be more prevalent under future climate-change scenarios, but data sets in this study contained few data in that range.
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Autor
Kumudini, S.;
Andrade, Fernando Hector;
Boote, K.J.;
Brown, G.A.;
Dzotsi, K.A.;
Edmeades, G.O.;
Gocken, T.;
Goodwin, M.;
Halter, A.L.;
Hammer, G.L.;
Hatfield, J.L.;
Jones, J.W.;
Kemanian, A.R.;
Kim, Sung Hyun;
Kiniry, J.;
Lizaso, J.I.;
Nendel, C.;
Nielsen, R.L.;
Parent, B.;
Stӧckle, C.O.;
Tardieu, F.;
Thomison, P.R.;
Timlin, D.J.;
Vyn, T.J.;
Wallach, D.;
Yang, H.S.;
Tollenaar, Matthijs;
Fuente
Agronomy Journal 106 (6) : 2087-2097 (2014)
Fecha
2014-12
Editorial
American Society of Agronomy
ISSN
0002-1962
1435-0645
1435-0645
Formato
pdf
Tipo de documento
artículo
Palabras Claves
Derechos de acceso
Abierto
Excepto donde se diga explicitamente, este item se publica bajo la siguiente descripción: Creative Commons Attribution-NonCommercial-ShareAlike 2.5 Unported (CC BY-NC-SA 2.5)