Number of the records: 1
Discrete anisotropic radiative transfer modelling of solar-induced chlorophyll fluorescence: Structural impacts in geometrically explicit vegetation canopies
- 1.
SYSNO ASEP 0547503 Document Type J - Journal Article R&D Document Type Journal Article Subsidiary J Článek ve WOS Title Discrete anisotropic radiative transfer modelling of solar-induced chlorophyll fluorescence: Structural impacts in geometrically explicit vegetation canopies Author(s) Malenovský, Z. (CZ)
Regaieg, O. (FR)
Yin, T. (CN)
Lauret, N. (FR)
Guilleux, J. (FR)
Chavanon, E. (FR)
Duran, N. (FR)
Janoutová, Růžena (UEK-B) RID, ORCID, SAI
Delavois, A. (FR)
Meynier, J. (FR)
Medjdoub, G. (FR)
Yang, P. (CN)
Van der Tol, C. (NL)
Morton, D. (US)
Cook, B. D. (US)
Gastellu-Etchegorry, J. P. (FR)Number of authors 16 Source Title Remote Sensing of Environment. - : Elsevier - ISSN 0034-4257
Roč. 263, SEP 15 (2021), s. 1-24Number of pages 24 s. Language eng - English Country US - United States Keywords sun-induced fluorescence ; monte-carlo ; reflectance ; photosynthesis ; scattering ; dart ; transmittance ; fluspect ; airborne ; traits ; dart ; Fluspect ; scope ; sif ; Sun-/shade-adapted leaves ; lai ; Clumping ; Wood Subject RIV EH - Ecology, Behaviour OECD category Environmental sciences (social aspects to be 5.7) R&D Projects LM2018123 GA MŠMT - Ministry of Education, Youth and Sports (MEYS) Research Infrastructure CzeCOS III - 90123 - Ústav výzkumu globální změny AV ČR, v. v. i. Method of publishing Limited access Institutional support UEK-B - RVO:86652079 UT WOS 000702738400002 EID SCOPUS 85109576689 DOI 10.1016/j.rse.2021.112564 Annotation Solar-induced fluorescence (SIF) is a subtle but informative optical signal of vegetation photosynthesis. Remotely sensed SIF integrates environmental, physiological and structural changes that alter photosynthesis at leaf, plant and canopy scales. Radiative transfer models are ideally suited to investigate the complex sources of variability in the SIF signal to guide the interpretation of SIF retrievals from airborne and space-borne platforms. Here, we coupled the Fluspect-Cx model of leaf optical properties and chlorophyll-a fluorescence with the Discrete Anisotropic Radiative Transfer (DART) model to upscale SIF from individual leaves to three-dimensional (3D) structurally explicit canopies. For one-dimensional homogeneous (turbid-like) canopies, DART-SIF was nearly identical to SIF simulated in two existing models, SCOPE and mSCOPE (RMSE <0.221 W.m(-2).mu m(-1).sr(-1)). DART simulations in geometrically explicit 3D canopies offered four important insights regarding the influence of vegetation structure on the multiangular top-of-canopy SIF signal. First, changes in the 3D canopy architecture of maize crops, represented by leaf density (leaf area index), and plant clumping (canopy closure) had a larger impact on SIF than the modelled photosynthetic efficiency distinction between sun-adapted and shade-adapted foliage. Second, clumping of leaves at the crop and stand levels was identified as one of the key driving factors of multi-angular anisotropy of red and farred SIF (686 and 740 nm) for both maize and eucalyptus canopies. Third, non-photosynthetic woody material had a significant impact on top-of-canopy SIF in modelled 3D forest stands. Wood shadowing decreased the photosynthetically active radiation absorbed by green leaves, and consequently the SIF emissions, by 10% in sparse and 17% in dense eucalyptus stands. The wood obstruction (blocking) effect, quantified as a relative difference of SIF escape probabilities from canopies with and without wood in the nadir viewing direction, decreased far-red SIF by 4-6% but it had a smaller and sometimes positive influence (by less than 2%) on red SIF. Fourth, DART 3D radiative budget profiles revealed that the majority of the SIF signal from a dense eucalyptus stand originated from the top 25% of the simulated canopy. Interestingly, the introduction of bark-covered woody elements did not alter the simulated balance and omnidirectional escape factor of red SIF in this upper canopy part but did raise significantly both of them in case of far-red SIF. These results demonstrate the importance of 3D radiative transfer and radiative budget simulations for investigating SIF interactions in structurally complex plant canopies and for a better understanding of spatiotemporal and multi-angular remote sensing SIF observations. Workplace Global Change Research Institute Contact Nikola Šviková, svikova.n@czechglobe.cz, Tel.: 511 192 268 Year of Publishing 2022 Electronic address https://www.sciencedirect.com/science/article/pii/S0034425721002844?via%3Dihub
Number of the records: 1