Diameter explains transient allocation of non-photosynthetic organs in trees

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Renfei Chen
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Abstract

A central issue in plant ecology is exploring universal rules and the mechanisms under which photosynthetic energies are allocated to different organ parts. Until recently, prevalent studies focused on testing either optimal allocation theory or allometric allocation theory in predicting plant biomass partitioning patterns. However, paying much attention to the stable state prevents the development of new biomass allocation theories in transient time scales. Here, based on theories in transients and the allometric relationships in plant traits, I develop general theoretical models to study the transient perturbations of plant biomass allocated to non-photosynthetic organ parts. With both simulation and empirical approaches, I investigate the effect of plant stem diameter at breast height (DBH) on the variation of biomass allocation patterns during plant ontogeny. Results show that increases in DBH can mitigate the magnitude of the perturbations of plant biomass and biomass fractions allocated to both plant stem and root parts. The findings are robust when either deterministic or stochastic models are conducted. Moreover, empirical analyses from a large forest database in Eurasia consistently support the predictions from the theoretical frameworks. In this paper, I draw attention to the transient allocation pattern of plant biomass for non-photosynthetic organs, and I find the significant role of DBH. This work has important implications in both theoretical breakthroughs and practical applications. It not only provides the foundation to test new biomass allocation hypotheses but also directs agricultural and forest management to achieve stabilized yields.

直径解释了树木非光合器官的瞬时分配
植物生态学的一个核心问题是探索光合作用在不同器官部位分配的普遍规律和机制。到目前为止,普遍的研究主要集中在验证最优分配理论或异速分配理论对植物生物量分配模式的预测。然而,对稳定状态的过多关注阻碍了新的瞬态时间尺度生物质分配理论的发展。本文基于瞬态理论和植物性状的异速生长关系,建立了研究植物生物量分配给非光合器官的瞬态扰动的一般理论模型。采用模拟和实证相结合的方法,研究了胸径对植物个体发育过程中生物量分配格局变化的影响。结果表明,增加胸径可以减轻植物生物量和分配给植物茎和根的生物量组分的扰动程度。无论采用确定性模型还是随机模型,结果都是稳健的。此外,欧亚大陆大型森林数据库的实证分析一致支持理论框架的预测。在本文中,我关注了植物生物量在非光合器官中的瞬时分配模式,并发现胸径在其中的重要作用。这项工作在理论突破和实际应用上都具有重要意义。它不仅为检验新的生物量分配假设提供了基础,而且指导农业和森林管理实现稳定产量。
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
CiteScore
7.20
自引率
4.30%
发文量
567
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