Jiayu Zhang, Elias Kaiser, Hanyi Zhang, Leo F M Marcelis, Silvere Vialet-Chabrand
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引用次数: 0
Abstract
Background: Quantifying plant transpiration via thermal imaging is desirable for applications in agriculture, plant breeding, and plant science. However, thermal imaging under natural non-steady state conditions is currently limited by the difficulty of quantifying thermal properties of leaves, especially specific heat capacity (Cp). Existing literature offers only rough estimates of Cp and lacks simple and accurate methods to determine it.
Results: We developed a non-invasive method to quantify k (the product of leaf thickness (lt), leaf density(ρ), and Cp), by fitting a leaf energy balance model to a leaf temperature (Tleaf) transient during and after a ~ 10 s light pulse. Cp was then estimated by dividing k by lt*ρ. Using this method, we quantified Cp for 13 horticultural and tropical plant species, and explored the relationship between Cp and leaf water content, specific leaf area and Tleaf response rate during the light pulse. Values of Cp ranged between 3200-4000 J kg-1 K-1, and were positively correlated with leaf water content. In species with very thick leaves, such as Phalaenopsis amabilis, we found leaf thickness to be a major factor in the temperature response to a short light pulse.
Conclusions: Our method allows for easy determination of leaf Cp of different species, and may help pave the way to apply more accurate thermal imaging under natural non-steady state conditions.
期刊介绍:
Plant Methods is an open access, peer-reviewed, online journal for the plant research community that encompasses all aspects of technological innovation in the plant sciences.
There is no doubt that we have entered an exciting new era in plant biology. The completion of the Arabidopsis genome sequence, and the rapid progress being made in other plant genomics projects are providing unparalleled opportunities for progress in all areas of plant science. Nevertheless, enormous challenges lie ahead if we are to understand the function of every gene in the genome, and how the individual parts work together to make the whole organism. Achieving these goals will require an unprecedented collaborative effort, combining high-throughput, system-wide technologies with more focused approaches that integrate traditional disciplines such as cell biology, biochemistry and molecular genetics.
Technological innovation is probably the most important catalyst for progress in any scientific discipline. Plant Methods’ goal is to stimulate the development and adoption of new and improved techniques and research tools and, where appropriate, to promote consistency of methodologies for better integration of data from different laboratories.
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