Abstract
A sufficient nitrogen (N) supply is mandatory for healthy crop growth, but negative consequences of N losses into the environment are known. Hence, deeply understanding and monitoring crop growth for an optimized N management is advisable. In this context, remote sensing facilitates the capturing of crop traits. While several studies on estimating biomass from spectral and structural data can be found, N is so far only estimated from spectral features. It is well known that N is negatively related to dry biomass, which, in turn, can be estimated from crop height. Based on this indirect link, the present study aims at estimating N concentration at field scale in a two-step model: first, using crop height to estimate biomass, and second, using the modeled biomass to estimate N concentration. For comparison, N concentration was estimated from spectral data. The data was captured on a spring barley field experiment in two growing seasons. Crop surface height was measured with a terrestrial laser scanner, seven vegetation indices were calculated from field spectrometer measurements, and dry biomass and N concentration were destructively sampled. In the validation, better results were obtained with the models based on structural data (R2 < 0.85) than on spectral data (R2 < 0.70). A brief look at the N concentration of different plant organs showed stronger dependencies on structural data (R2: 0.40–0.81) than on spectral data (R2: 0.18–0.68). Overall, this first study shows the potential of crop-specific across‑season two-step models based on structural data for estimating crop N concentration at field scale. The validity of the models for in-season estimations requires further research.
Highlights
Nitrogen (N) is a fundamental component of proteins and essential for any kind of living
This survey pursued a novel approach of estimating N concentration based on the indirect link to structural data
Crop surface height was measured by terrestrial laser scanning (TLS), seven vegetation indices (VI) were calculated from field spectrometer measurements, and destructive measurements of dry biomass and N concentration were carried out
Summary
Nitrogen (N) is a fundamental component of proteins and essential for any kind of living. When canopy closure is reached, plants compete for light and invest more N in stem elongation to place their leaves to the better-illuminated top layers [4,5] Another role for the crop development can be attributed to the stem, as plants use stem N as source for grain N later in the growing season [3]. If this storage is insufficient and further sources are missing, such as N released by natural leaf senescence or soil N, plants let leaves die off for the required N [3]. N plays the most important role in the fertilization of arable and forage cropping systems [6]
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