Does reduced intraspecific competition of the dominant species in intercrops allow for a higher population density?

Qi Wang; Wei Bai; Zhanxiang Sun; Dongsheng Zhang; Yue Zhang; Ruonan Wang; Jochem B. Evers; Tjeerd‐Jan Stomph; Wopke van derWerf; Chen Feng; Lizhen Zhang

doi:10.1002/fes3.270

Food and Energy Security (May 2021)

Does reduced intraspecific competition of the dominant species in intercrops allow for a higher population density?

Qi Wang,
Wei Bai,
Zhanxiang Sun,
Dongsheng Zhang,
Yue Zhang,
Ruonan Wang,
Jochem B. Evers,
Tjeerd‐Jan Stomph,
Wopke van derWerf,
Chen Feng,
Lizhen Zhang

Affiliations

Qi Wang: State Key Laboratory of Severe Weather (LASW) Chinese Academy of Meteorological Science Beijing China
Wei Bai: Tillage and Cultivation Research Institute Liaoning Academy of Agricultural Sciences Shenyang China
Zhanxiang Sun: Tillage and Cultivation Research Institute Liaoning Academy of Agricultural Sciences Shenyang China
Dongsheng Zhang: College of Agriculture Shanxi Agricultural University Taigu China
Yue Zhang: College of Agricultural Resources and Environmental Sciences China Agricultural University Beijing China
Ruonan Wang: College of Agricultural Resources and Environmental Sciences China Agricultural University Beijing China
Jochem B. Evers: Centre for Crop Systems Analysis (CSA) Wageningen University Wageningen The Netherlands
Tjeerd‐Jan Stomph: Centre for Crop Systems Analysis (CSA) Wageningen University Wageningen The Netherlands
Wopke van derWerf: Centre for Crop Systems Analysis (CSA) Wageningen University Wageningen The Netherlands
Chen Feng: Tillage and Cultivation Research Institute Liaoning Academy of Agricultural Sciences Shenyang China
Lizhen Zhang: College of Agricultural Resources and Environmental Sciences China Agricultural University Beijing China

DOI: https://doi.org/10.1002/fes3.270
Journal volume & issue: Vol. 10, no. 2
pp. 285 – 298

Abstract

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Abstract Dominant 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.

Published in Food and Energy Security

ISSN: 2048-3694 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Agriculture: Agriculture (General)
Website: https://onlinelibrary.wiley.com/journal/20483694

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