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Published online 1 January 1998
Published in Agron J 90:73-79 (1998)
© 1998 American Society of Agronomy
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Phenological Temperature Response of Maize

Douglas W. Stewart* and Lianne M. Dwyer

Agric. & Agri-Food Canada, Eastern Cereal & Oilseed Res. Ctr., Ctr., Ottawa, ON K1A 0C6, Canada

Lori L. Carrigan

Pioneer Hybrid Int., Plant Breeding Div., Willmar, MN 56201

* Corresponding author (stewartd{at}em.agr.ca).

Variability of development rate estimates across locations and years using the current heat unit system of growing degree-days (GDD) with maximum and minimum temperature thresholds of 30 and 10°C (GDD30,10) limits predictability of maturity in hybrid maize (Zea mays L.). Data sets of daily maximum and minimum air temperatures and dates of maize development stages were collected for a range of hybrids at locations in Canada and the northern USA (39° to 45° N lat). Data were analyzed to improve the temperature response functions for maize at different stages of development. Results indicate that during vegetative growth, phenological response to mean daily air temperature followed a sigmoidal curve beginning below 5°C, with maximum response to temperatures between 25 and 30°C. During reproductive growth, the temperature response function was flat from 0 to 12°C and rose significantly only with mean daily air temperatures greater than this range. A general thermal index (GTI) based on these two response functions improved estimation of maturity dates by 50% over estimates made using GDD30,10 (SE of 6.7 d for GTI and 13.6 d for GDD30,10 in estimating time from planting to maturity). The greatest improvement using GTI occurred for the reproductive period (SE of 5.8 d using GTI, compared with 12.1 d using GDD30,10). These results suggest that incorporating the temperature response function reported in this paper would improve prediction of maize development.

Contribution no. 961105 of the Eastern Cereal & Oilseed Res. Ctr.

Received for publication January 16, 1997.


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