树木在结冰过程中释放出的二氧化碳脉冲为避免冬季栓塞提供了新的视角。

Bursts of CO2 released during freezing offer a new perspective on avoidance of winter embolism in trees.

作者信息

Lintunen A, Lindfors L, Kolari P, Juurola E, Nikinmaa E, Hölttä T

机构信息

Department of Forest Sciences, University of Helsinki, Post Office Box 27, FI-00014, Helsinki, Finland

Department of Forest Sciences, University of Helsinki, Post Office Box 27, FI-00014, Helsinki, Finland Department of Physics, University of Helsinki, Post Office Box 64, FI-00014, Helsinki, Finland.

出版信息

Ann Bot. 2014 Dec;114(8):1711-8. doi: 10.1093/aob/mcu190. Epub 2014 Sep 24.

DOI:10.1093/aob/mcu190

PMID:25252688

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4649691/

Abstract

BACKGROUND AND AIMS

Woody plants can suffer from winter embolism as gas bubbles are formed in the water-conducting conduits when freezing occurs: gases are not soluble in ice, and the bubbles may expand and fill the conduits with air during thawing. A major assumption usually made in studies of winter embolism formation is that all of the gas dissolved in the xylem sap is trapped within the conduits and forms bubbles during freezing. The current study tested whether this assumption is actually valid, or whether efflux of gases from the stem during freezing reduces the occurrence of embolism.

METHODS

CO2 efflux measurements were conducted during freezing experiments for saplings of three Scots pine (Pinus sylvestris) and three Norway spruce (Picea abies) trees under laboratory conditions, and the magnitudes of the freezing-related bursts of CO2 released from the stems were analysed using a previously published mechanistic model of CO2 production, storage, diffusion and efflux from a tree stem. The freezing-related bursts of CO2 released from a mature Scots pine tree growing in field conditions were also measured and analysed.

KEY RESULTS

Substantial freezing-related bursts of CO2 released from the stem were found to occur during both the laboratory experiments and under field conditions. In the laboratory, the fraction of CO2 released from the stem ranged between 27 and 96 % of the total CO2 content within the stem.

CONCLUSIONS

All gases dissolved in the xylem sap are not trapped within the ice in the stem during freezing, as has previously been assumed, thus adding a new dimension to the understanding of winter embolism formation. The conduit water volume not only determines the volume of bubbles formed during freezing, but also the efficiency of gas efflux out of the conduit during the freezing process.

摘要

背景与目的

木本植物可能会遭受冬季栓塞，因为在结冰时导水管道中会形成气泡：气体在冰中不可溶，解冻时气泡可能会膨胀并使管道充满空气。冬季栓塞形成研究中通常做出的一个主要假设是，木质部汁液中溶解的所有气体都被困在导管内，并在结冰时形成气泡。本研究测试了这一假设是否实际有效，或者结冰期间茎中气体的流出是否会减少栓塞的发生。

方法

在实验室条件下，对三株苏格兰松（Pinus sylvestris）和三株挪威云杉（Picea abies）树苗进行结冰实验时，测量了二氧化碳的流出量，并使用先前发表的关于树干中二氧化碳产生、储存、扩散和流出的机理模型，分析了从茎中释放的与结冰相关的二氧化碳爆发量。还测量并分析了在田间条件下生长的一棵成熟苏格兰松树释放的与结冰相关的二氧化碳爆发量。

主要结果

在实验室实验和田间条件下，均发现茎中会出现大量与结冰相关的二氧化碳爆发。在实验室中，从茎中释放的二氧化碳占茎中总二氧化碳含量的比例在27%至96%之间。

结论

如先前假设的那样，结冰期间并非所有溶解在木质部汁液中的气体都被困在茎中的冰内，这为理解冬季栓塞形成增添了新的维度。导管中的水量不仅决定了结冰期间形成的气泡体积，还决定了结冰过程中气体从导管中流出的效率。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7597/4649691/d0f45c2f297c/mcu19001.jpg

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树木在结冰过程中释放出的二氧化碳脉冲为避免冬季栓塞提供了新的视角。

Bursts of CO2 released during freezing offer a new perspective on avoidance of winter embolism in trees.

作者信息

机构信息

出版信息

BACKGROUND AND AIMS

METHODS

KEY RESULTS

CONCLUSIONS

背景与目的

方法

主要结果

结论

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