同位素稳定态或非稳定态蒸腾？整树箱的新见解。

Isotopic steady state or non-steady state transpiration? Insights from whole-tree chambers.

机构信息

School of Life and Environmental Sciences, The University of Sydney, Private Bag 4011, Narellan, NSW 2567, Australia.

College of Science and Engineering, James Cook University, Cairns, QLD 4879, Australia.

出版信息

Tree Physiol. 2024 Nov 5;44(11). doi: 10.1093/treephys/tpae125.

DOI:10.1093/treephys/tpae125

PMID:39365945

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11555434/

Abstract

Unravelling the complexities of transpiration can be assisted by understanding the oxygen isotope composition of transpired water vapour (δE). It is often assumed that δE is at steady state, thereby mirroring the oxygen isotope composition of source water (δsource), but this assumption has never been tested at the whole-tree scale. This study utilized the unique infrastructure of 12 whole-tree chambers enclosing Eucalyptus parramattensis E.C.Hall trees to measure δE along with concurrent temperature and gas exchange data. Six chambers tracked ambient air temperature and six were exposed to an ambient +3 °C warming treatment. Day time means for δE were within 1.2‰ of δsource (-3.3‰) but varied considerably throughout the day. Our observations show that E. parramattensis trees are seldom transpiring at isotopic steady state over a diel period, but transpiration approaches source water isotopic composition over longer time periods.

摘要

解析蒸腾作用的复杂性可以通过理解散发的水汽的氧同位素组成（δE）来辅助。通常假设 δE 处于稳定状态，从而反映出源水的氧同位素组成（δsource），但这一假设从未在整树尺度上进行过检验。本研究利用 12 个全树室的独特基础设施来测量 δE 以及同时的温度和气体交换数据，这些全树室包围着桉树 Parramattensis E.C.Hall 树。六个树室跟踪环境空气温度，六个暴露在环境+3°C 的增温处理下。δE 的日间平均值在 δsource（-3.3‰）的 1.2‰以内，但在一天中变化很大。我们的观察表明，桉树 Parramattensis 树在一天的时间内很少处于同位素稳定状态下蒸腾，但在较长时间内，蒸腾作用接近源水的同位素组成。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7c08/11555434/d46f78eeb59c/tpae125f1.jpg

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同位素稳定态或非稳定态蒸腾？整树箱的新见解。

Isotopic steady state or non-steady state transpiration? Insights from whole-tree chambers.

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