Abstract
Sensing and mapping element distributions in plant tissues and its growth environment has great significance for understanding the uptake, transport, and accumulation of nutrients and harmful elements in plants, as well as for understanding interactions between plants and the environment. In this study, we developed a 3-dimensional elemental mapping system based on laser-induced breakdown spectroscopy that can be deployed in- field to directly measure the distribution of multiple elements in living plants as well as in the soil. Mapping is performed by a fast scanning laser, which ablates a micro volume of a sample to form a plasma. The presence and concentration of specific elements are calculated using the atomic, ionic, and molecular spectral characteristics of the plasma emission spectra. Furthermore, we mapped the pesticide residues in maize leaves after spraying to demonstrate the capacity of this method for trace elemental mapping. We also used the system to quantitatively detect the element concentrations in soil, which can be used to further understand the element transport between plants and soil. We demonstrate that this method has great potential for elemental mapping in plant tissues and soil with the advantages of 3-dimensional and multi-elemental mapping, in situ and in vivo measurement, flexible use, and low cost.
Highlights
Sensing and imaging elemental concentrations in biological tissues has great importance for understanding uptake, transport, and accumulation of both nutritious and harmful elements in plants as well as cell absorption and formation processes [1]
Three types of elemental imaging and mapping methods are used for biological tissues: X-ray microscopy-based methods [2,7,8], mass spectroscopy-based methods [2,9,10,11,12] and fluorescent probes [13,14]
We developed a removable elemental mapping system based on micro-Laser-induced breakdown spectroscopy (LIBS), LipsImag
Summary
Sensing and imaging elemental concentrations in biological tissues has great importance for understanding uptake, transport, and accumulation of both nutritious and harmful elements in plants as well as cell absorption and formation processes [1]. For the X-ray microscopy methods, the commonly used methods are scanning or transmission electron microscopy with energy-dispersive X-ray analysis (SEM-EDX or TEM-EDX) and proton/particle-induced X-ray emission (PIXE) [2,7] The former requires a vacuum sampling system, but the latter can only analyze elements lighter than Na. Upon development and establishment of synchrotron radiation (SR) systems, certain researchers have used X-ray fluorescence spectroscopy based on synchrotron radiation (SRXRF) and X-ray absorption spectroscopy based on synchrotron
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