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叶片性状对蒸腾氧同位素特征时间动态的影响及其对大气水汽的影响。

Impact of Leaf Traits on Temporal Dynamics of Transpired Oxygen Isotope Signatures and Its Impact on Atmospheric Vapor.

作者信息

Dubbert Maren, Kübert Angelika, Werner Christiane

机构信息

Ecosystem Physiology, University Freiburg Freiburg, Germany.

出版信息

Front Plant Sci. 2017 Jan 18;8:5. doi: 10.3389/fpls.2017.00005. eCollection 2017.

DOI:10.3389/fpls.2017.00005
PMID:28149303
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5241305/
Abstract

Oxygen isotope signatures of transpiration (δ ) are powerful tracers of water movement from plant to global scale. However, a mechanistic understanding of how leaf morphological/physiological traits effect δ is missing. A laser spectrometer was coupled to a leaf-level gas-exchange system to measure fluxes and isotopic signatures of plant transpiration under controlled conditions in seven distinct species (). We analyzed the role of stomatal conductance ( ) and leaf water content () on the temporal dynamics of δ following changes in relative humidity (). Changes in rH were applied from 60 to 30% and from 30 to 60%, which is probably more than covering the maximum step changes occurring under natural conditions. Further, the impact of and on isotopic non-steady state isofluxes was analyzed. Following changes in , temporal development of δ was well described by a one-pool modeling approach for most species. Isofluxes of δ were dominantly driven by stomatal control on , particularly for the initial period of 30 min following a step change. Hence, the deviation of isofluxes from isotopic steady state can be large, even though plants transpire near to isotopic steady state. Notably, not only transpiration rate and stomatal conductance, but also the leaf traits stomatal density (as a measure of g) and leaf water content are significantly related to the time constant (τ) and non-steady-state isofluxes. This might provide an easy-to-access means of a priori assumptions for the impact of isotopic non-steady-state transpiration in various ecosystems. We discuss the implications of our results from leaf to ecosystem scale.

摘要

蒸腾作用的氧同位素特征(δ )是从植物到全球尺度水分运动的有力示踪剂。然而,对于叶片形态/生理特征如何影响δ 的机制理解尚缺。一台激光光谱仪与一个叶片水平的气体交换系统相连,用于在可控条件下测量7个不同物种的植物蒸腾通量和同位素特征()。我们分析了气孔导度()和叶片含水量()对相对湿度()变化后δ 时间动态的作用。相对湿度从60%降至30%以及从30%升至60%,这可能超过了自然条件下发生的最大阶跃变化范围。此外,分析了和对同位素非稳态等通量的影响。在变化之后,对于大多数物种,δ 的时间发展通过单池建模方法得到了很好的描述。δ 的等通量主要由气孔对的控制驱动,特别是在阶跃变化后的最初30分钟内。因此,即使植物在接近同位素稳态下蒸腾,等通量与同位素稳态的偏差仍可能很大。值得注意的是,不仅蒸腾速率和气孔导度,而且叶片特征气孔密度(作为g的度量)和叶片含水量都与时间常数(τ)和非稳态等通量显著相关。这可能为各种生态系统中同位素非稳态蒸腾作用的影响提供一种易于获取的先验假设方法。我们讨论了从叶片到生态系统尺度的结果的意义。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c447/5241305/adace55be697/fpls-08-00005-g0007.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c447/5241305/cb0c33f3dc39/fpls-08-00005-g0001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c447/5241305/7b55a1293023/fpls-08-00005-g0002.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c447/5241305/24b651573e69/fpls-08-00005-g0006.jpg
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