Leaf removal effects on light absorption in virtual Riesling canopies (Vitis vinifera)

IF 2.6 Q1 AGRONOMY
C. Bahr, Dominik Schmidt, M. Friedel, K. Kahlen
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引用次数: 5

Abstract

Leaf removal is a standard vineyard management technique to influence grape composition or to reduce disease pressure; however, the timing and intensity of leaf removal is a widely discussed issue. The interplay of different goals and effects over time does not make experimental studies any easier. To gain insight into positive and negative consequences of leaf removal on grapevine development, a first step can be to study how leaf removal affects the canopy’s light absorption using a dynamic model approach. Functional–structural plant models combine canopy architecture with physiological processes and allow analysing canopy interaction with the environment with great topological detail. The functional–structural plant model Virtual Riesling simulates Riesling vines in a vineyard set-up depending on temperature and plant management. We implemented leaf removal and applied this method in or above the bunch zone to compare the light absorption in canopies. Leaf removal in the bunch zone led to greater loss of absorbed light, but canopies of both scenarios could compensate for most of the loss during the simulation time frame. Compensation was mainly driven by lateral leaves closing the gaps induced by leaf removal and by leaves in the proximity of the leaf removal zones, re-exposed to light. Results showed similar effects as observed in in vivo studies; hence, we suggest extending these simulations to investigate other effects linked to light distribution such as berry sunburn. Simple modifications of implemented leaf removal techniques also allow for testing different application scopes and their impact on canopy light absorption.
叶片去除对虚拟雷司令冠层光吸收的影响
摘叶是影响葡萄成分或降低病害压力的标准葡萄园管理技术;然而,叶片去除的时间和强度是一个广泛讨论的问题。随着时间的推移,不同目标和效果的相互作用并没有使实验研究变得更容易。为了深入了解叶片去除对葡萄藤生长的积极和消极影响,第一步可以使用动态模型方法研究叶片去除如何影响冠层的光吸收。功能结构植物模型将冠层结构与生理过程结合起来,并允许分析冠层与环境的相互作用,具有很大的拓扑细节。功能-结构植物模型虚拟雷司令模拟雷司令葡萄藤在葡萄园设置取决于温度和植物管理。我们实现了叶片去除,并将这种方法应用于束区或束区以上,以比较冠层的光吸收。束带的叶片去除导致吸收光的损失更大,但在模拟时间框架内,两种情况下的冠层都可以补偿大部分损失。补偿主要是由侧叶填补因叶片移除引起的间隙和叶片靠近叶片移除区重新暴露在光下驱动的。结果显示与在体内研究中观察到的效果相似;因此,我们建议将这些模拟扩展到研究与光分布有关的其他影响,如浆果晒伤。对实施的叶片去除技术的简单修改也允许测试不同的应用范围及其对冠层光吸收的影响。
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
in silico Plants
in silico Plants Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
4.70
自引率
9.70%
发文量
21
审稿时长
10 weeks
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