Feasibility of early fertilization of maize with 15 N application to preceding cover crop

Momesso, Letusa; Crusciol, Carlos Alexandre Costa; do Nascimento, Carlos Antonio Costa; Soratto, Rogério P.; Canisares, Lucas Pecci; Moretti, Luiz Gustavo; Rosolem, Ciro Antonio; Trivelin, Paulo Cesar Ocheuze; Kuramae, Eiko Eurya; Cantarella, Heitor

doi:https://doi.org/10.1016/j.eja.2022.126485

Feasibility of early fertilization of maize with 15 N application to preceding cover crop

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Feasibility of early fertilization of maize with 15 N application to preceding cover crop

Momesso, Letusa; Crusciol, Carlos Alexandre Costa; do Nascimento, Carlos Antonio Costa; Soratto, Rogério P.; Canisares, Lucas Pecci; Moretti, Luiz Gustavo; Rosolem, Ciro Antonio; Trivelin, Paulo Cesar Ocheuze; Kuramae, Eiko Eurya; Cantarella, Heitor

(2022) European Journal of Agronomy, volume 135, pp. 1 - 11

(Article)

Abstract

Early nitrogen (N) application on live cover crops or their residues is a potential alternative for supplying N demand while enhancing the yield of subsequent cash crops in tropical regions. The objective of applying N on live forage grasses or their residues to no-till (NT) systems is to promote the ... read more gradual release of N via straw decomposition to the subsequent crop. However, the N use efficiency by the subsequent crop under early fertilization has not been determined in the end of growing season. The aim of this study was to evaluate whether the most cultivated tropical forage grasses can supply the N demand and enhance the grain yields of maize via the N recovery when N is applied with different timings than the conventional method. A 3-year field experiment was performed using palisade grass [(Urochloa brizantha (syn. Brachiaria)] and ruzigrass (U. ruziziensis) as cover crops with four N application timings to agricultural system: (i) no-N, zero N application; (ii) CC+N, 120 kg N ha−1 applied on live cover crops 35 days before maize seeding; (iii) St+N, 120 kg N ha−1 applied on cover crops straw 1 day before seeding; and (iii) Nv4, conventional method of sidedress N application at the maize V4 (four leaf) growth stage. Except control, all N treatments received 40 kg N ha−1at maize seeding, totalizing 160 kg N ha−1. Straw decomposition and cover crop N accumulation were greater in the treatments in which N fertilizer was applied on palisade grass compared with ruzigrass. High maize yields were achieved with N application on palisade grass or its residues or according to the conventional method, with yields of 13.2, 13.2 and 13.6 Mg ha−1, respectively. Similarly, high maize yields were obtained when N was applied on ruzigrass residues or according to the conventional method (12.1 and 11.8 Mg ha−1, respectively). However, regardless of cover crop species, N recovery was highest when N fertilizer was applied via the conventional method. Additionally, most of the N in maize at harvest came from the soil when N fertilizer was applied to live palisade grass. Thus, best recovery of N fertilizer in the grain occurred in maize fertilized using the conventional method. Our results indicate that agricultural systems characterized by high dry matter from palisade grass have the potential to recycle and supply N to subsequent maize. Although palisade grass combined with early N fertilizer application may enhance maize response and yield, the current conventional method of N fertilizer application on maize allows higher recovery from N fertilizer while increasing the maize yield in tropical food production.

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Keywords: N fertilizer, Brachiaria spp., Crop residues, Tropical agriculture, Zea mays L., Taverne, Agronomy and Crop Science, Soil Science, Plant Science

DOI: https://doi.org/10.1016/j.eja.2022.126485

ISSN: 1161-0301

Publisher: Elsevier

Note: Funding Information: Grants from CAPES – Coordination for the Improvement of Higher Level Personnel [PDSE 88881.187743/2018–01] to LM, FAPESP [grant number 2015/17953–6] for partial funding, and FAPESP [2016/12317–7] to CACN. This work was undertaken as part of NUCLEUS, a virtual joint center to deliver enhanced N–use efficiency via an integrated soil–plant systems approach for the United Kingdom and Brazil. Funded in the United Kingdom by the Biotechnology and Biological Sciences Research Council [Grant BB/N013201/1] under the Newton Fund scheme; and in Brazil by FAPESP–São Paulo Research Foundation [Grant 2015/50305–8]; FAPEG–Goiás Research Foundation [Grant 2015–10267001479]; and FAPEMA–Maranhão Research Foundation [Grant RCUK–02771/16]. The authors would like to acknowledge the National Council for Scientific and Technological Development (CNPq) for awards for excellence in research to CACC, RPS, CAR, PCOT and HC. Publication number XXXX of the Netherlands Institute of Ecology (NIOO-KNAW). Funding Information: Grants from CAPES – Coordination for the Improvement of Higher Level Personnel [PDSE 88881.187743/2018–01] to LM, FAPESP [grant number 2015/17953–6] for partial funding, and FAPESP [ 2016/12317–7 ] to CACN. This work was undertaken as part of NUCLEUS, a virtual joint center to deliver enhanced N–use efficiency via an integrated soil–plant systems approach for the United Kingdom and Brazil. Funded in the United Kingdom by the Biotechnology and Biological Sciences Research Council [Grant BB/N013201/1 ] under the Newton Fund scheme; and in Brazil by FAPESP–São Paulo Research Foundation [Grant 2015/50305–8 ]; FAPEG–Goiás Research Foundation [Grant 2015–10267001479]; and FAPEMA–Maranhão Research Foundation [Grant RCUK–02771/16 ]. The authors would like to acknowledge the National Council for Scientific and Technological Development (CNPq) for awards for excellence in research to CACC, RPS, CAR, PCOT and HC. Publication number XXXX of the Netherlands Institute of Ecology (NIOO-KNAW). Publisher Copyright: © 2022 Elsevier B.V.

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