Guidelines for in-season nitrogen application for maize (Zea mays L.) based on soil and terrain properties

Nitrogen (N) fertilizers are often applied to maize (Zea mays L.) in excess of economically optimal rates because of the uncertainty of dealing with seasonal and spatial variability. A better understanding of the relationships among field, apparent soil electrical conductivity (ECa), elevation, slope and seasonal characteristics is therefore essential for performing optimal variable-rate N applications. This study focused on responses during the exponential growth phase, when it is critical that N supply be not limited. Measurements at high spatial resolution allowed to understand the effects of the relationships among N, ECa, elevation, slope and season on future yield formation. The study was conducted over three years (2005–2007). Mid-season growth responses to applied N were greatest where ECa levels were high and elevation was low in 2005 and 2007, but not in 2006. Areas with slope ≥1 degree were also more responsive to N rates. Overall best mid-season growth was found in areas of low ECa, high Elevation and low Slope. However, the best responses to in-season N fertilization were found in areas with opposite properties (high ECa, low Elevation and high Slope). Indeed, relatively high rates of in-season N were needed to enhance crop growth in areas of high ECa, low Elevation and high Slope, which are characteristic of unfavourable growth conditions. In counterpart, lower N rates were sufficient for optimal growth in soils at low ECa high Elevation and low Slope. Also, despite the fact that conditions of high soil variability were specifically selected for the study, the effects and interactions reported for soil NO3–N content were small. The interaction of ECa with early seasonal precipitation is likely a key relationship to consider in variable-rate N application: low-lying areas with fine soil texture showed the greatest dependence on weather for optimal N rates. Indeed, the relationships among factors influencing the response to in-season N fertilization were stronger when seasonal conditions were particularly favourable to maize growth. These results are fundamental to the establishment of in-season application rules for spatially variable N algorithms.

► We studied the impact of field properties and weather conditions on corn response to in-season N fertilization.
► High N rates were effective in areas with high ECa, low Elevation and high Slope (unfavourable to growth).
► Lower N rates were sufficient in areas with low ECa, high Elevation and low Slope.
► Effects on field features on N response were greater in good seasonal conditions.