| Literature DB >> 30309727 |
J Mason Earles1, Thomas N Buckley2, Craig R Brodersen3, Florian A Busch4, F Javier Cano5, Brendan Choat5, John R Evans4, Graham D Farquhar4, Richard Harwood6, Minh Huynh6, Grace P John7, Megan L Miller8, Fulton E Rockwell9, Lawren Sack7, Christine Scoffoni10, Paul C Struik11, Alex Wu12, Xinyou Yin11, Margaret M Barbour13.
Abstract
Leaves are a nexus for the exchange of water, carbon, and energy between terrestrial plants and the atmosphere. Research in recent decades has highlighted the critical importance of the underlying biophysical and anatomical determinants of CO2 and H2O transport, but a quantitative understanding of how detailed 3D leaf anatomy mediates within-leaf transport has been hindered by the lack of a consensus framework for analyzing or simulating transport and its spatial and temporal dynamics realistically, and by the difficulty of measuring within-leaf transport at the appropriate scales. We discuss how recent technological advancements now make a spatially explicit 3D leaf analysis possible, through new imaging and modeling tools that will allow us to address long-standing questions related to plant carbon-water exchange.Entities:
Keywords: 3D; leaf anatomy; leaf hydraulic conductance; mesophyll conductance; photosynthesis
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Year: 2018 PMID: 30309727 DOI: 10.1016/j.tplants.2018.09.005
Source DB: PubMed Journal: Trends Plant Sci ISSN: 1360-1385 Impact factor: 18.313