| REMOTE SENSING OF ENVIRONMENT | 卷:253 |
| Assessing the contribution of understory sun-induced chlorophyll fluorescence through 3-D radiative transfer modelling and field data | |
| Article | |
| Hornero, A.1,3 North, P. R. J.1 Zarco-Tejada, P. J.2,3 Rascher, U.4 Martin, M. P.5 Migliavacca, M.6 Hernandez-Clemente, R.1 | |
| [1] Swansea Univ, Dept Geog, Swansea SA2 8PP, W Glam, Wales | |
| [2] Univ Melbourne, Dept Infrastruct Engn, Melbourne Sch Engn MSE, Fac Vet & Agr Sci FVAS,Sch Agr & Food, Melbourne, Vic, Australia | |
| [3] CSIC, Inst Agr Sostenible IAS, Alameda Obispo S-N, Cordoba 14004, Spain | |
| [4] Forschungszentrum Julich, Inst Bio & Geosci, IBG 2 Plant Sci, Leo Brandt Str, D-52425 Julich, Germany | |
| [5] CSIC, Environm Remote Sensing & Spect Lab, SpecLab, Albasanz 26-28, Madrid 28037, Spain | |
| [6] Max Planck Inst Biogeochem, Hanks Knoll Str 10, D-07745 Jena, Germany | |
| 关键词: Chlorophyll fluorescence; Heterogeneous canopies; Hyperspectral; HyPlant; Radiative transfer modelling; SIF; Understory; | |
| DOI : 10.1016/j.rse.2020.112195 | |
| 来源: Elsevier | |
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【 摘 要 】
A major international effort has been made to monitor sun-induced chlorophyll fluorescence (SIF) from space as a proxy for the photosynthetic activity of terrestrial vegetation. However, the effect of spatial heterogeneity on the SIF retrievals from canopy radiance derived from images with medium and low spatial resolution remains uncharacterised. In images from forest and agricultural landscapes, the background comprises a mixture of soil and understory and can generate confounding effects that limit the interpretation of the SIF at the canopy level. This paper aims to improve the understanding of SIF from coarse spatial resolutions in heterogeneous canopies by considering the separated contribution of tree crowns, understory and background components, using a modified version of the FluorFLIGHT radiative transfer model (RTM). The new model is compared with others through the RAMI model intercomparison framework and is validated with airborne data. The airborne campaign includes high-resolution data collected over a tree-grass ecosystem with the HyPlant imaging spectrometer within the FLuorescence EXplorer (FLEX) preparatory missions. Field data measurements were collected from plots with a varying fraction of tree and understory vegetation cover. The relationship between airborne SIF calculated from pure tree crowns and aggregated pixels shows the effect of the understory at different resolutions. For a pixel size smaller than the mean crown size, the impact of the background was low (R-2 > 0.99; NRMSE < 0.01). By contrast, for a pixel size larger than the crown size, the goodness of fit decreased (R-2 < 0.6; NRMSE > 0.2). This study demonstrates that using a 3D RTM model improves the calculation of SIF significantly (R-2 = 0.83, RMSE = 0.03 mW M-2 sr(-1) nm(-1)) when the specific contribution of the soil and understory layers are accounted for, in comparison with the SIF calculated from mixed pixels that considers only one layer as background (R-2 = 0.4, RMSE = 0.28 mW M-2 sr(-1) nm(-1)). These results demonstrate the need to account for the contribution of SIF emitted by the understory in the quantification of SIF within tree crowns and within the canopy from aggregated pixels in heterogeneous forest canopies.
【 授权许可】
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| Files | Size | Format | View |
|---|---|---|---|
| 10_1016_j_rse_2020_112195.pdf | 11027KB |  download |
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