Plant spatial configurations and their influences on phenological traits of cereal and legume crops under maize-based intercropping systems

Journal of Sustainable Agriculture and Environment Pub Date : 2024-06-20 DOI:10.1002/sae2.12110

Michael W. Kinyua, Monicah W. Mucheru-Muna, Peter Bolo, Job Kihara

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Abstract

Introduction

Intercropping systems have a great potential for crop diversification thus increasing smallholder systems' resilience to climate change while improving soil health. However, optimal benefits associated with intercropping systems are rarely realised because of the interspecific competition for growth resources among the intercropped species.

Methodology

Six trials were established in the high and low rainfall agroecological zones of Babati district in Tanzania to assess how promising cropping systems with different plant spatial configurations would influence the phenological development of intercropped maize, bean and pigeonpea. Cropping systems under study included a sole maize system rotated with a pigeonpea-bean intercrop dubbed Doubled-up legume (DUL), maize-pigeonpea system both with and without de-topping, an innovation comprising double maize rows alternated with pigeonpea and beans (Mbili-Mbili), maize-pigeonpea system with two maize seeds sown within a 50 cm intra-row space, a vertical-architecture Meru H513-pigeonpea system and a farmer practice.

Results

Branch formation was significantly higher in DUL than in maize-based systems (p ≤ 0.05). Seasonal weather had upto 30% influence on pigeonpea flowering, with DUL having highest (p ≤ 0.05) flower production. The rate of pigeonpea branch and flower production in Mbili-Mbili was stable across seasons relative to other maize-pigeonpea systems. Doubled-up legume and farmer practice had pigeonpea litter yield of between 1 and 2 t ha⁻¹ which was at least 0.5 t ha⁻¹ higher than in maize-based systems (p ≤ 0.05). During the period preceding early maize reproductive stages, Mbili-Mbili increased light interception by 30% and 63% compared to maize-based systems and DUL, respectively. Maize toppings had higher (94%) P content than stover biomass that remained until harvest.

Conclusion

Overall, maize-legume systems had higher intercropping efficacy than sole maize system, both in interception use efficiency, soil mulch cover, among other soil health benefits. Mbili-Mbili and DUL also had increased phenological benefits on intercropped legumes however, the latter was prone to seasonal weather variability.

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玉米间作系统下的植物空间配置及其对谷类和豆类作物物候性状的影响

引言间作系统具有作物多样化的巨大潜力，可提高小农系统对气候变化的适应能力，同时改善土壤健康。然而，由于间作物种间对生长资源的竞争，很少能实现间作系统的最佳效益。方法在坦桑尼亚巴巴提地区的高降雨量和低降雨量农业生态区建立了六个试验，以评估具有不同植物空间配置的种植系统将如何影响间作玉米、豆类和鸽子豆的物候发展。所研究的种植系统包括：与鸽子豆间作（被称为 "加倍豆科植物（DUL）"）轮作的单一玉米种植系统、去顶和不去顶的玉米-鸽子豆种植系统、由玉米双行交替种植鸽子豆和豆子（Mbili-Mbili）组成的创新种植系统、在 50 厘米行间距内播种两粒玉米种子的玉米-鸽子豆种植系统、垂直结构的 Meru H513-鸽子豆种植系统以及农民实践。结果 DUL 系统的分枝率明显高于玉米系统（p ≤ 0.05）。季节性天气对鸽子豆开花的影响高达 30%，DUL 的花产量最高（p ≤ 0.05）。与其他玉米-鸽子豆系统相比，Mbili-Mbili 的鸽子豆枝条和花朵产量在不同季节都很稳定。加倍种植豆科植物和农民的做法使鸽子豆枯枝产量介于 1 吨/公顷和 2 吨/公顷之间，比玉米种植系统至少高出 0.5 吨/公顷（p ≤ 0.05）。在玉米早期生殖期之前，与以玉米为基础的系统和 DUL 相比，Mbili-Mbili 的截光率分别提高了 30% 和 63%。与收获前的秸秆生物量相比，玉米表皮的 P 含量更高（94%）。结论总体而言，玉米-豆科植物间作系统在截获利用效率、土壤覆盖物以及其他土壤健康益处方面都比单一玉米系统具有更高的功效。Mbili-Mbili 和 DUL 还增加了间作豆科植物的物候效益，但后者易受季节性天气变化的影响。

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Journal of Sustainable Agriculture and Environment

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2.60

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