Night transpiration of peanut affects interspecific water complementarity and use efficiency in maize/peanut intercropping

IF 6.5 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-03-06 DOI:10.1016/j.agwat.2025.109420

Tianran Sun , Zhanxiang Sun , Zhe Zhang , Yue Zhang , Yajiaoxue Guo , Jinyu Zhang , Jiayi Nie , Zhi Dong , Zeshan Zhang , Chenjia Zhang , Xu Zhang , Chen Feng , Lizhen Zhang

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引用次数: 0

Abstract

Interspecific competition for soil water between species in intercropping is critical for understanding the mechanism of resource use and overyielding in a mixture cropping system, however, it is difficult to measure plant transpiration because of lacking direct and precise measuring methods. In this study, we aim to directly measure plant transpiration of each species using sap flow meters with the heat ratio method (HRM) and to explore the interspecific interactions in water use in intercropping. The experiment was conducted in 2021–2023 under semiarid rainfed conditions in Liaoning province, China. Three treatments were compared, i.e. sole maize, sole peanut, and maize/peanut intercropping with 2 maize rows maize and 4 rows peanut. The total transpiration (TTr) of intercropped maize was 53.5 % lower than that of monocropped maize; however, considering the land use proportion of maize in the intercropping (33 %), intercropped maize plants increased TTr by 39.5 %. The water productivity (WP), defined as the above ground dry matter produced by unit crop transpiration, for intercropped maize (8.04 g m⁻² mm⁻¹) was 43.9 % higher than that for the monoculture (5.60 g m⁻² mm⁻¹), due to its strong competitive ability for soil water, resulting from the border row effects in the intercropping. The average dry matter of intercropping maize was 1497 g m⁻², which was 13.6 % higher than that of mono-cropping maize. For intercropped peanut, the TTr was 165 % of that in monocropped peanut, which was 148 % higher than the expected (67 %, land use proportion of peanut), which was probably due to a night transpiration in understory crops. The night sap velocity of intercropped peanut was 9.62 cm h⁻¹ over three years (2021–2023), while the night sap flow of dominant species maize and sole peanut were close to zero. The WP of intercropped peanut (2.75 g m⁻² mm⁻¹) was 35.6 % lower than that of the monoculture (4.27 g m⁻² mm⁻¹). Intercropping increased maize transpiration and produced more above ground dry matter. However, it reduced peanut growth and caused more nighttime transpiration, likely due to changes in microclimate conditions. Our study provides a useful information to understand the mechanism of interspecific affiliations in water use in mixing cropping systems and helps farmers to optimize agronomy managements of intercrops. The results could also contribute to the improvements for evapotranspiration simulation models.

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花生夜间蒸腾作用影响玉米/花生间作种间水分互补和利用效率

间作土壤水分的种间竞争是了解混作系统资源利用和超产机制的关键，但由于缺乏直接、精确的测量方法，对植物蒸腾作用的测量存在困难。本研究旨在利用热比法（HRM）直接测量每个物种的植物蒸腾，并探讨间作水分利用的种间相互作用。试验于2021-2023年在中国辽宁省半干旱雨养条件下进行。比较了单玉米、单花生和玉米/花生间作2行玉米和4行花生的3种处理。间作玉米的总蒸腾量（TTr）比单作玉米低53.5 %；但考虑到间作玉米的土地利用比例（33 %），间作玉米可使TTr提高39.5 %。间作玉米的水分生产力（WP），即单位作物蒸腾产生的地上干物质（8.04 g m−2 mm−1）比单作玉米（5.60 g m−2 mm−1）高43.9 %，这是由于间作中边行效应对土壤水分的竞争能力较强。间作玉米的平均干物质为1497 g m−2，比单作玉米高13.6 %。间作花生的TTr为单作花生的165 %，高于预期值（花生土地利用比例为67 %）148 %，这可能与林下作物夜间蒸腾有关。间作花生夜间液流速度（2021-2023）为9.62 cm h−1，而优势种玉米和单花生夜间液流接近于零。间作花生的WP（2.75 g m−2 mm−1）比单作降低35.6 %（4.27 g m−2 mm−1）。间作增加了玉米蒸腾作用，增加了地上干物质产量。然而，它减少了花生的生长并引起了更多的夜间蒸腾作用，可能是由于小气候条件的变化。本研究为了解混作系统中种间水分利用的关联机制提供了有益的信息，并有助于农民优化间作的农艺管理。这些结果也有助于改进蒸散发模拟模型。

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来源期刊

Agricultural Water Management 农林科学-农艺学

CiteScore

12.10

自引率

14.90%

发文量

648

审稿时长

4.9 months

期刊介绍： Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.