Abstract
AbstractDominant species in intercropping experience less resource competition compared with its monoculture. This reduced competition for resources may allow cultivating the dominant species at an increased density in intercropping to obtain greater yield. However, experimental results are inconclusive when the optimal within row density in the sole crop is not well established. Here, we conducted a two‐year experiment to test the hypothesis that optimal within row plant density of dominant species in intercropping would be higher in the intercrop than in the sole crop. We tested three maize densities (3, 4.5, and 6 plants m−1) in both sole maize and two replacement designed intercrops. The row configurations of two intercrops are two rows maize intercropped with four rows peanut (M2P4) and four rows maize intercropped with four rows peanut (M4P4). Peanut was grown at the same plant density of 12 plants m−1 row in both sole crop and intercrops. The results indicated that increasing maize density from the optimal density in monoculture is not worthy of promotion to improve yield in intercropping, which denied our hypothesis. The land equivalent ratios (LER) in the dry year (2017) were higher than the wet year (2016). Maize yields per unit area of the whole intercropping system were highest with densities of 4.5 and 6 plants m−1 row, with no significant difference between these two densities. Maximum maize yields in sole cropping were obtained with maize densities of 6 plants m−1 row. Intercropping provided higher yields at low and intermediate sole crop maize densities, but not at high sole crop maize density. Average land equivalent ratios at 3, 4.5, and 6 plants m−1 of maize were 1.09, 1.04, and 0.95 in 2016, and 1.07, 1.10, and 1.02 in 2017. Our results suggest that intercropping performs better at conditions with less resources than adequate resources.
Highlights
Intercropping is the cultivation of multiple crop species in the same field during all or part of their growing period
To determine yield of maize and peanut in the intercrops and sole crops, all plants in an 8 m−2 (6 m−2 for M2P4) final subsampling area in the center of each plot were harvested on 30 September of each year (Zhang et al, 2020)
Kernel number per cob was higher in border rows than in inner rows or sole maize, and it decreased with density in the sole crop and in the inner rows in the intercropping, but in border rows, it was similar at 3 and 4.5 plants m−1 row and only dropped when density was increased to 6 plants m−1 row. 100-kernel weight was higher in wet 2016 than in dry 2017, while the difference between plant densities and configuration was not significant in 2016. 100-kernel weight in 2017 tended to be higher in border rows than in inner rows or sole maize especially at a maize density of 4.5 plants m−1 row, and tended to decrease with plant density (Figure 5e,f)
Summary
National Key R&D Program of China, Grant/Award Number: 2016YFD0300202; China Institute of Water Resources and Hydropower Research Team Construction and Talent Development Project, Grant/Award Number: JZ0145B752017; International Cooperation and Exchange of the National Science Foundation of China, Grant/Award Number: 31461143025; China Scholarship Council, Grant/Award Number: 201706350221; European Union’s Horizon 2020 Programme for Research and Innovation, Grant/Award Number: 727217
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