Summary
Quantitative relationships for key processes influencing N response were derived from measurements of inorganic N in soil, the weights and N contents of foliage and tubers made at intervals during growth of maincrop potatoes in 11 N fertilizer experiments.
Apparent mineralization rates (calculated from measurements of N uptake and inorganic N in the top metre and averaged over the growth period) were remarkably similar from site to site despite wide differences in the textures, water contents and organic matter contents of the soils. They were mostly about 0.78 kg N ha−1 m−1 d−1.
Inorganic N in the top 50 cm of soil was rapidly removed by the crop until it fell on all sites to a low value (about 4 μg N cm−3) which was maintained for the remainder of the growth period. When N fertilizer was applied, growth rate until at least the end of July was always well defined by a single coefficient in a previously derived equation. Average values of this coefficient for each of the soil types and for each of the years in which the experiments were carried out were within 20% of each other.
The minimum %N in the dry matter needed to permit maximum growth rate declined with increase in plant weight in a similar manner to that previously found for other crops.
Equations were found for the partition of assimilate and of nitrogen between the foliage and tubers. The coefficients in them were little affected by whether or not N fertilizer was applied.
According to these relationships the maximum potential dry weight yield of tubers is 20 t ha−1 and requires the crop to contain at least 290 kg N ha−1.
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Greenwood, D.J., Neeteson, J.J. & Draycott, A. Response of potatoes to N fertilizer: Quantitative relations for components of growth. Plant Soil 85, 163–183 (1985). https://doi.org/10.1007/BF02139622
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DOI: https://doi.org/10.1007/BF02139622