Abstract
Heterogeneity exists in the vertical distribution of the biochemical components of crops. A leaf chlorophyll deficiency occurs in the bottom- and middle-layers of crops due to nitrogen stress and leaf senescence. Some studies used multi-angular remote sensing data for estimating the vertical distribution of the leaf chlorophyll content (LCC). However, these studies performed LCC inversion of different vertical layers using a fixed view zenith angle (VZA), but rarely considered the contribution of the components of the non-target layers to the spectral response. The main goal of this work was to determine the LCC of different vertical layers of the canopy of winter wheat (Triticum aestivum L.), using multi-angular remote sensing and spectral vegetation indices. Different combinations of VZAs were used for obtaining the LCC of different layers. The results revealed that the responses of the transformed chlorophyll in reflectance absorption index (TCARI) and modified chlorophyll absorption in reflectance index (MCARI)/optimized soil-adjusted vegetation index (OSAVI) to the upper-layer LCC were strongest at VZA 10°. For the middle-layer LCC, the response was strongest at 30°, but the response was significantly lower than that of the upper-layer. For the bottom-layer LCC, the responses were weak due to the obscuring effect of the upper- and middle-layer; thus, the LCC inversion of the bottom-layer data was not optimal for a single VZA. The optimal VZA or VZA combinations for LCC estimation were VZA 10° for the upper-layer LCC (TCARI with coefficient of determination (R2) = 0.69, root mean square error (RMSE) = 4.80 ug/cm2, MCARI/OSAVI with R2 = 0.73, RMSE = 4.17 ug/cm2), VZA 10° and 30° for the middle-layer LCC (TCARI with R2 = 0.17, RMSE = 4.81 ug/cm2, MCARI/OSAVI with R2 = 0.17, RMSE = 4.76 ug/cm2), and VZA 10°, 30°, and 50° for the bottom-layer LCC (TCARI with R2 = 0.40, RMSE = 6.29 ug/cm2, MCARI/OSAVI with R2 = 0.40, RMSE = 6.36 ug/cm2). The proposed observation strategy provided a significantly higher estimation accuracy of the target layer LCC than the single VZA approach, and demonstrated the ability of canopy multi-angular spectral reflectance to accurately estimate the wheat canopy chlorophyll content vertical distribution.
Highlights
The importance of analyzing the leaf chlorophyll content (LCC) in vegetation has been recognized for decades [1,2,3,4]
The LCC of the upper-layer began to increase due to the utilization of light energy, resulting in a significant difference in the chlorophyll content between the upper, middle, and bottom-layers
The results showed that different view zenith angle (VZA) combinations were adopted to monitor the LCC at different layers, which could reduce the monitoring difficulty caused by the increase in the number of VZAs on the premise of ensuring the monitoring accuracy and was more suitable for this study
Summary
The importance of analyzing the leaf chlorophyll content (LCC) in vegetation has been recognized for decades [1,2,3,4]. The LCC depends on the photosynthetic capacity, developmental stage, and canopy stress [5,6,7]. Nitrogen (N) exhibits a pronounced heterogeneity in the vertical distribution in crop canopies since it is highly mobile [9,10]. If the N demand of a crop is higher than its uptake, N is efficiently translocated to the photosynthetically most active leaves in the top canopy [11]. Nitrogen is an important substance for chlorophyll synthesis. The deficiency of nitrogen is accompanied by the decrease of chlorophyll content, which is manifested as leaf wither and yellow
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