Abstract
BackgroundPhotosynthetic pigments participating in the absorption, transformation and transfer of light energy play a very important role in plant growth. While, the spatial distribution of foliar pigments is an important indicator of environmental stress, such as pests, diseases and heavy metal stress.ResultsIn this paper, in situ quantitative visualization of chlorophyll and carotenoid was realized by combining the Raman spectroscopy with calibration model transfer, and a laboratory Raman spectral model was successfully extended to a portable field spectral measurement. Firstly, a nondestructive and fast model for determination of chlorophyll and carotenoid in tea leaf was established based on confocal micro-Raman spectrometer in the laboratory. Then the spectral model was extended to a real-time foliar map scanning spectra of a field portable Raman spectrometer through calibration model transfer, and the spectral variation between the confocal micro-Raman spectrometer in the laboratory and the portable Raman spectrometer were effectively corrected by the direct standardization (DS) algorithm. The portable map scanning Raman spectra of the tea leaves after the model transfer were got into the established quantitative determination model to predict the concentration of photosynthetic pigments at each pixel of the tea leaves. The predicted photosynthetic pigments concentration of each pixel was imaged to illustrate the distribution map of foliar pigments. Statistical analysis showed that the predicted pigment contents were highly correlated with the real contents.ConclusionsIt can be concluded that the Raman spectroscopy was applicable for in situ, non-destructive and rapid quantitative detecting and imaging of photosynthetic pigment concentration in tea leaves, and the spectral detection model established based on the laboratory Raman spectrometer can be applied to a portable field spectrometer for quantitatively imaging of the foliar pigments.
Highlights
Photosynthetic pigments participating in the absorption, transformation and transfer of light energy play a very important role in plant growth
Establishment of quantitative determination model Raman spectral quantitative determination of photosynthetic pigments in tea leaf As shown in Table 2, different pretreatment methods produced different results referring to the values of Coefficient of determination (R2) and root mean square error (RMSE), indicating that pretreatment has a great
Based on the Raman spectral pretreatment method combined with the Competitive adaptive re-weighted algorithm (CARS) characteristic bands selection, the quantitative determination models of chlorophyll and carotenoid concentration were established by regression analysis
Summary
Photosynthetic pigments participating in the absorption, transformation and transfer of light energy play a very important role in plant growth. The spatial distribution of foliar pigments is an important indicator of environmental stress, such as pests, diseases and heavy metal stress. Photosynthetic pigments including chlorophyll a (Chl-a), chlorophyll b (Chl-b), and total carotenoids (Car) play a very important role in plant growth. The spatial distribution of foliar pigments is an important indicator of environmental stress, such as pests, diseases and heavy metal stress [3, 4]. Developing a method for nondestructive detection and quantitative visualization of foliar photosynthetic pigment content is an important task for plant protection, cultivation and tea processing [5]
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