Tillering and nitrogen economy of low-density maize crops

For the maize (Zea mays L.) crop, tillering is promoted in resource-abundant seasons (e.g., rainfalls, nutrient availability) at low plant densities. For this crop husbandry, farmers rarely use nitrogen (N) fertilization. Particularly, the impact of tillering on N economy processes and the effects o...

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Bibliographic Details
Published in:Field crops research 2024-04, Vol.309, p.109310, Article 109310
Main Authors: Mejía Álvarez, C.A., Rotili, D.H., D’Andrea, K.E., Ciampitti, I.A., Abeledo, L.G., Maddonni, G.Á.
Format: Article
Language:English
Subjects:
Argentina
biomass production
corn
evolution
grain yield
harvest index
hybrids
irrigated farming
low rainfall environments
maize
nitrogen
nitrogen content
nitrogen fertilization
nitrogen internal efficiency
nutrient availability
plant cultural practices
plant density
soil
tillering
Zea mays
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Summary:For the maize (Zea mays L.) crop, tillering is promoted in resource-abundant seasons (e.g., rainfalls, nutrient availability) at low plant densities. For this crop husbandry, farmers rarely use nitrogen (N) fertilization. Particularly, the impact of tillering on N economy processes and the effects of N availability on grain yield generation of tillered maize crops have yet to be studied. (i) To compare the evolution of biomass and N uptake for tillered and de-tillered (manually removed) maize crops, and (ii) to evaluate the impact of tillers on nitrogen internal efficiency for biomass (NIEB), grain yield (NIEG), harvest index (HI) and N harvest index (NHI). Two irrigated field experiments in different cropping seasons (2017–2018 and 2018–2019) with a tillering-prone maize hybrid were conducted in Buenos Aires, Argentina. Treatments were a combination of plant density [3 levels, 4 pl m−2 = D4; 2 pl m−2 = D2, including an additional tiller removal treatment during the whole tillering window at D2, D2(-T)] and two soil N availabilities [unfertilized= 60 kg N ha−1 of native soil N (N-) and fertilized= 220 kg N ha−1 of native soil + applied N (N+)]. Biomass accumulation, N uptake, HI, NHI, grain N concentration (GrainN%), NIEB and NIEG were analyzed at the shoot (main shoot and tillers) and crop levels. At D2 with N+, tillered crops had greater biomass and N uptake than non-tillered crops but did not compensate for the density reduction compared to D4. NIEB of tillers was similar to that of main shoots, but HI, NIEG and NHI of tillers were lower than those of main shoots. A negative relationship between crop NIEG and GrainN% was sustained for main shoots, but not for tillers due to the low and variable HI of these secondary shoots. In low-density maize management scenarios, tillers increase resource capture in resource-abundant seasons, generating greater crop biomass through a sustained NIEB. However, an intrinsic lower HI of tillers (and NIEG) versus main shoots decreases NIEG of tillered crops. Knowledge gaps regarding the impact of tillers on N economy of maize crops were answered for the first time. New issues arise: to compare the N dilution curves for main shoots and tillers and to quantify post-flowering N uptake of tillers and N remobilization from tillers to main shoots. •Low densities promote tillering in maize crops, but farmers apply low N.•Tillers increased crop biomass production and N uptake.•Tillers had lower HI, NHI and GrainN% than main shoot
ISSN:0378-4290
1872-6852
DOI:10.1016/j.fcr.2024.109310