Influence of planting pattern on peanut ecosystem daytime net carbon uptake, evapotranspiration, and water-use efficiency using the eddy-covariance method

IF 3.5 Q1 AGRONOMY Frontiers in Agronomy Pub Date : 2023-06-15 DOI:10.3389/fagro.2023.1204887
Gengsheng Zhang, M. Leclerc, N. Singh, R. Tubbs, Walter Scott Montfort
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引用次数: 1

Abstract

Peanut is planted in a pattern of either single or twin rows in Georgia, USA. However, limited attention has been paid to the impact of planting pattern on the carbon footprint and how the net carbon uptake is intertwined with the amount of water used to determine the ecosystem water-use efficiency (WUE) in peanut. This paper reports on the relationship between the amount of carbon produced to the amount of water used in peanut, carbon dioxide flux, and crop evapotranspiration of peanut in a single- or in a twin-row planting pattern measured using the eddy-covariance method. To the best of our knowledge, the present study is unique in that it examines for the first time the effect of planting pattern on the net carbon uptake and WUE. The two-year study took place in contrasting weather conditions with the 2016 year experiencing a higher vapor pressure deficit and lower precipitation than in the 2018 year. In this study, field-scale daytime net carbon ecosystem exchange (CO2 fluxes), ET and WUE of single- and twin-row peanut were compared using the eddy-covariance technique. Results showed that in 2018, both the net carbon uptake from the atmosphere and the WUE of twin-row peanut were significantly greater than those in the single-row peanut by 7-10% and ~9% respectively, for pod filling and seed maturity growth stages (aGDD 1000-2000 and aGDD > 2000). In 2016, the net daytime carbon uptake and WUE of peanut were similar for both planting patterns during pod filling (aGDD 1000-2000). Higher precipitation and lower VPD in 2018 likely resulted in greater peanut yield in twin-row as compared to single-row with abundant precipitation. Owing to the fast canopy growth rate in twin-row peanut, results suggest that during the vegetative stage (aGDD<500) in 2016, both daytime net carbon uptake from the atmosphere and WUE were considerably greater in twin-row than single-row by 32% and 27%, respectively. Given that in both years, the ET from both planting patterns was similar, it appears that the determination of WUE in both planting patterns was more impacted by changes in daytime net carbon uptake than evapotranspiration. The results of this study suggest the possibility that the higher WUE at the critical stages of twin-row peanut in 2018 are likely to lead to greater yield than single-row peanut. This should be confirmed with further year-to-year investigations.
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种植模式对花生生态系统日间净碳吸收、蒸散和水分利用效率的影响
在美国乔治亚州,花生以单行或双排的模式种植。然而,人们对种植模式对碳足迹的影响以及净碳吸收如何与用于确定花生生态系统用水效率(WUE)的水量交织在一起的关注有限。本文报道了用涡度协方差法测量的单列或双列种植模式下花生的产碳量与用水量、二氧化碳通量和作物蒸散量之间的关系。据我们所知,本研究的独特之处在于,它首次考察了种植模式对净碳吸收和WUE的影响。这项为期两年的研究是在对比天气条件的情况下进行的,与2018年相比,2016年的蒸汽压赤字更高,降水量更低。本研究采用涡度协方差技术,比较了单列和双列花生的田间白天净碳生态系统交换(CO2通量)、ET和WUE。结果显示,2018年,在荚充和种子成熟生长阶段(aGDD 1000-2000和aGDD>2000),双列花生的大气净碳吸收和WUE分别显著高于单列花生7-10%和~9%。2016年,两种种植模式的花生在荚期的日间净碳吸收和WUE相似(aGDD 1000-2000)。与降水丰富的单列相比,2018年较高的降水量和较低的VPD可能导致双列花生产量更高。由于双列花生的冠层生长速度快,研究结果表明,在2016年营养期(aGDD<500),双列花生白天从大气中的净碳吸收和水分利用效率均显著高于单列,分别高出32%和27%。考虑到在这两年中,两种种植模式的ET相似,似乎两种种植方式中WUE的确定更受日间净碳吸收变化的影响,而不是蒸散。本研究结果表明,2018年双列花生关键阶段较高的水分利用率可能比单列花生产量更高。这一点应通过进一步的年度调查予以确认。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Frontiers in Agronomy
Frontiers in Agronomy Agricultural and Biological Sciences-Agricultural and Biological Sciences (miscellaneous)
CiteScore
4.80
自引率
0.00%
发文量
123
审稿时长
13 weeks
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