Monitoring Mega-Crown Leaf Turnover from Space



Bush ER, Mitchard ETA, Silva TSF, Dimoto E, Dimbonda P, Makaga L & Abernethy K (2020) Monitoring Mega-Crown Leaf Turnover from Space. Remote Sensing, 12 (3), Art. No.: 429.

Spatial and temporal patterns of tropical leaf renewal are poorly understood and poorly parameterized in modern Earth System Models due to lack of data. Remote sensing has great potential for sampling leaf phenology across tropical landscapes but until now has been impeded by lack of ground-truthing, cloudiness, poor spatial resolution, and the cryptic nature of incremental leaf turnover in many tropical plants. To our knowledge, satellite data have never been used to monitor individual crown leaf phenology in the tropics, an innovation that would be a major breakthrough for individual and species-level ecology and improve climate change predictions for the tropics. In this paper, we assessed whether satellite data can detect leaf turnover for individual trees using ground observations of a candidate tropical tree species, Moabi (Baillonella toxisperma), which has a mega-crown visible from space. We identified and delineated Moabi crowns at Lopé NP, Gabon from satellite imagery using ground coordinates and extracted high spatial and temporal resolution, optical, and synthetic-aperture radar (SAR) timeseries data for each tree. We normalized these data relative to the surrounding forest canopy and combined them with concurrent monthly crown observations of new, mature, and senescent leaves recorded from the ground. We analyzed the relationship between satellite and ground observations using generalized linear mixed models (GLMMs). Ground observations of leaf turnover were significantly correlated with optical indices derived from Sentinel-2 optical data (the normalized difference vegetation index and the green leaf index), but not with SAR data derived from Sentinel-1. We demonstrate, perhaps for the first time, how the leaf phenology of individual large-canopied tropical trees can directly influence the spectral signature of satellite pixels through time. Additionally, while the level of uncertainty in our model predictions is still very high, we believe this study shows that we are near the threshold for orbital monitoring of individual crowns within tropical forests, even in challenging locations, such as cloudy Gabon. Further technical advances in remote sensing instruments into the spatial and temporal scales relevant to organismal biological processes will unlock great potential to improve our understanding of the Earth system.

phenology; leaf turnover; tropics; Afrotropics; Sentinel; NDVI; GLI; SAR

Remote Sensing: Volume 12, Issue 3

FundersANPN Agence Nationale des Parcs Nationaux
Publication date29/02/2020
Publication date online29/01/2020
Date accepted by journal23/01/2020

People (2)


Professor Katharine Abernethy
Professor Katharine Abernethy

Professor, Biological and Environmental Sciences

Dr Thiago Silva
Dr Thiago Silva

Senior Lecturer, Biological and Environmental Sciences

Projects (1)