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Fine-scale leaf chlorophyll distribution across a deciduous forest through two-step model inversion from Sentinel-2 data

Yingjie Li, Qingmiao Ma, Jing M. Chen, Holly Croft, Xiangzhong Luo, Ting Zheng, Cheryl Rogers, Jane Liu

2021Remote Sensing of Environment50 citationsDOIOpen Access PDF

Abstract

Leaf chlorophyll content (LCC) is a key physiological trait and is crucial for monitoring plant health and accurately modeling the terrestrial carbon cycle. However, spatially-continuous information on LCC variability at fine time-steps, and at fine spatial resolutions across regional spatial extents, is sparse. In this study, we improved a physically-based, two-step inversion approach by using an advanced canopy-to-leaf reflectance conversion model to estimate LCC at fine spatial resolution (20 m) from Sentinel-2 Multi-Spectral Instrument (MSI) data. The first step is to convert MSI canopy reflectance to leaf reflectance using look-up tables constructed from a geometric optical model (4-Scale). The second step is to estimate LCC from the modeled leaf reflectance using the PROSPECT-5 leaf optical model. Both leaf reflectance and LCC derived from MSI were validated against field measurements at a mixed temperate forest site in Canada to examine the accuracy of leaf area index (LAI) and LCC retrievals. The results demonstrate robust canopy-level inversions with strong relationships between measured and MSI-derived leaf reflectance (R2 = 0.995, p < 0.001, RMSE = 0.0143). The modeled LCC results were also strong when compared to measured LCC samples: R2 = 0.849, p < 0.001, and RMSE = 0.304 μg/cm2, respectively. The most important Sentinel-2 MSI band for LAI and LCC derivation was centered at 705 nm (Band 5). Importantly, this two-step radiative transfer inversion approach substantially improved upon the current LAI and LCC algorithms adopted by the Sentinel-2 Application Platform, which underestimated LAI by 52.93% and overestimated LCC by 44.45%. This work highlights the potential of the physically-based two-step inversion method for deriving leaf and canopy traits from Sentinel-2 at very fine spatial and temporal resolutions, for a wide range of terrestrial ecological applications.

Topics & Concepts

Remote sensingLeaf area indexEnvironmental scienceCanopyAtmospheric radiative transfer codesInversion (geology)Radiative transferReflectivityMean squared errorDeciduousBidirectional reflectance distribution functionScale (ratio)Spatial ecologyMathematicsBotanyGeologyOpticsGeographyStatisticsPhysicsCartographyEcologyBiologyPaleontologyStructural basinRemote Sensing in AgricultureLeaf Properties and Growth MeasurementUrban Heat Island Mitigation
Fine-scale leaf chlorophyll distribution across a deciduous forest through two-step model inversion from Sentinel-2 data | Litcius