A survey of proximal methods for monitoring leaf phenology in temperate deciduous forests-Reference-Cited by-同舟云学术

A survey of proximal methods for monitoring leaf phenology in temperate deciduous forests

Published:2020-09-25 Issue: Volume: Page:
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Author:

Soudani Kamel^ORCID,Delpierre Nicolas^ORCID,Berveiller Daniel^ORCID,Hmimina Gabriel,Pontailler Jean-Yves,Seureau Lou,Vincent Gaёlle,Dufrêne Éric

Abstract

AbstractTree phenology is a major driver of forest-atmosphere mass and energy exchanges. Yet tree phenology has historically not been recorded at flux measurement sites. Here, we used seasonal time-series of ground-based NDVI (Normalized Difference Vegetation Index), RGB camera GCC (Greenness Chromatic Coordinate), broad-band NDVI, LAI (Leaf Area Index),fAPAR (fraction of Absorbed Photosynthetic Active Radiation), CC (Canopy Closure),fRvis(fraction of Reflected Radiation) and GPP (Gross Primary Productivity) to predict six phenological markers detecting the start, middle and end of budburst and of leaf senescence in a temperate deciduous forest. We compared them to observations of budburst and leaf senescence achieved by field phenologists over a 13-year period. GCC, NDVI and CC captured very well the interannual variability of spring phenology (R2> 0.80) and provided the best estimates of the observed budburst dates, with a mean absolute deviation (MAD) less than 4 days. For the CC and GCC methods, mid-amplitude (50%) threshold dates during spring phenological transition agreed well with the observed phenological dates. For the NDVI-based method, on average, the mean observed date coincides with the date when NDVI reaches 25% of its amplitude of annual variation. For the other methods, MAD ranges from 6 to 17 days. GPP provides the most biased estimates. During the leaf senescence stage, NDVI- and CC-derived dates correlated significantly with observed dates (R2=0.63 and 0.80 for NDVI and CC, respectively), with MAD less than 7 days. Our results show that proximal sensing methods can be used to derive robust phenological indexes. They can be used to retrieve long-term phenological series at flux measurement sites and help interpret the interannual variability and decadal trends of mass and energy exchanges.Highlights

We used 8 indirect methods to predict the timing of phenological events.

GCC, NDVI and CC captured very well the interannual variation of spring phenology.

GCC, NDVI and CC provided the best estimates of observed budburst dates.

NDVI and CC derived-dates correlated with observed leaf senescence dates.

Publisher

Cold Spring Harbor Laboratory

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