Abstract
Soil nitrogen (N) content plays a vital role in agriculture and biogeochemical processes, ranging from the N fertilization management for intensive agricultural production to the patterns of N cycling in agroecological systems. While proximal sensing in laboratory settings can achieve ideal soil N estimation accuracy, the estimation and mapping by using remote sensing methods in a large spatial scale diplays low ability. A new hyperspectral imager with 166 spectral channels, the ZY1-02D, makes possible the detection of subtle but important spectral features of soil. This study aimed at exploring the capability of the ZY1-02D to estimate and map the topsoil N content of the black soil-covered farmlands in northeast China. To this aim, 646 soil samples from study sites were collected, processed, spectrally and geochemically measured for the soil N sensitive bands detection and partial least squares regression (PLSR) calibration and validation. The sensitive bands detection results showed an appealing regularity of the variability and stable tendency of the soil N sensitive spectral bands with the change of the sample size. Based on this, we compared the estimation capacity of the models developed with the full wavelength spectra and the models developed with the sensitive bands. The estimation based on ZY1-02D full wavelength spectral reflectance were robust, with R2 of 0.64 in validation. Further, the results of model developed with the sensitive bands showed better validation accuracy with R2 of 0.66 and were applied to create a map of topsoil N content of farmlands in the northeast China black soil area. The results demonstrated that sensitive bands modelling could enhance the accuracy of the estimation and simplify model, and what is more, showed the ideal capability of ZY1-02D for soil N content estimation at the regional scale.
Highlights
Introduction published maps and institutional affilA valuable agricultural farmland resource, black soils [1,2,3], are suffering from degradation of soil fertility as a result of over-exploitation, soil erosion and the abuse of fertilizers in recent years, which seriously threatens the climate conditions and the food security of the world [4,5]
Even though the R’ spectra increased the region of the high correlation bands than the results of R spectra, such discontinuity may lead to a significant variation of the correlation coefficient caused by the slight band anomaly, and lead to the inaccuracy of the N content estimation modelling based on the sensitive bands
This study demonstrated that the ZY1-02D (AHSI) showed an ideal capability for topsoil nitrogen content estimation and mapping at the regional scale
Summary
Introduction published maps and institutional affilA valuable agricultural farmland resource, black soils [1,2,3], are suffering from degradation of soil fertility as a result of over-exploitation, soil erosion and the abuse of fertilizers in recent years, which seriously threatens the climate conditions and the food security of the world [4,5]. The capacity to achieve agronomic management optimization and intensive farming, and to achieve safe and sustainable development of agriculture partly depends on a better monitoring of soil nutrient contents [6,7]. The concentration of nitrogen (N) in the topsoil of farmlands is the main indicator of soil nutrient status [8], and the N fertilization is the important management intervention for intensive agricultural production [9,10,11]. How to estimate and map topsoil N content in black soil-covered farmlands is an essential research target for black soil resource protection and sustainable agricultural development. How to estimate and map topsoil N content in black soil-covered farmlands is an essential research target for black soil resource protection and sustainable agricultural development. iations.
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