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Development of a nitrogen recommendation tool for corn considering static and dynamic variables

Puntel, Laila
European journal of agronomy 2019
corn, data collection, fertilizer rates, heat stress, nitrates, nitrogen, nitrogen fertilizers, planting date, prediction, regression analysis, simulation models, soil depth, soil organic matter, soil water, weather, yield forecasting, Argentina
Many soil and weather variables can affect the economical optimum nitrogen (N) rate (EONR) for maize. We classified 54 potential factors as dynamic (change rapidly over time, e.g. soil water) and static (change slowly over time, e.g. soil organic matter) and explored their relative importance on EONR and yield prediction by analyzing a dataset with 51 N trials from central-west region of Argentina. Across trials, the average EONR was 113 ± 83 kg N ha-1 and the average optimum yield was 12.3 ± 2.2 Mg ha-1, which is roughly 50% higher than the current N rates and yields obtained by maize producers in that region. Dynamic factors alone explained 50% of the variability in the EONR whereas static factors explained only 20%. Best EONR predictions resulted by combining one static variable (soil depth) together with four dynamic variables (number of days with precipitation > 20 mm, residue amount, soil nitrate at planting, and heat stress around silking). The resulting EONR model had a mean absolute error of 39 kg N ha-1 and an adjusted R2 of 0.61. Interestingly, the yield of the previous crop was not an important factor explaining EONR variability. Regression models for yield at optimum and at zero N fertilization rate as well as regression models to be used as forecasting tools at maize planting time were developed and discussed. The proposed regression models are driven by few and easy to measure variables such as precipitation and fill the space between very simple (minimum to no inputs) and very complex EONR prediction tools such as simulation models. In view of increasing data availability our proposed models can be further improved and deployed across environments.