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Scientists draw ‘wall-to-wall’ map of carbon storage of forests

US: A study published in Nature Climate Change claimed that tropical vegetation contains 21 percent more carbon than previous studies had suggested. Using a combination of remote sensing and field data, scientists from Woods Hole Research Center (WHRC), Boston University, and the University of Maryland were able to produce the first ‘wall-to-wall’ map (with a spatial resolution of 500 m x 500 m) of carbon storage of forests, shrublands, and savannas in the tropics of Africa, Asia, and South America. Colours on the map represent the amount of carbon density stored in the vegetation in a continuum fashion (featured in figure below).
 Tropical deforestation is considered a major source of the greenhouse gases that cause climate change, releasing as much as 1.1 billion tons of carbon into the atmosphere each year. Based on new data in this study, researchers believe that current models may overestimate the net flux of carbon into the atmosphere due to tropical vegetation loss by 11 to 12 percent. For countries trying to meet their greenhouse gases reporting requirements under the United Nations Framework Convention on Climate Change (UNFCCC), these new data are particularly important.
Lead author Alessandro Baccini, an assistant scientist at WHRC, explained that the new data set provides a spatially and temporally consistent estimate of carbon stock and a stronger foundation for estimating carbon emissions by better characterizing the carbon density of the forest that has been lost. “For the first time we were able to derive accurate estimates of carbon densities using satellite LiDAR observations in places that have never been measured,” said Baccini. “This is like having a consistent, very dense pantropical forest inventory.”
In many developing nations, deforestation is the largest source of emissions of greenhouse gases. In order to reliably report emissions to the UNFCCC, and to participate in international schemes such as Reducing Emissions from Deforestation and Forest Degradation (REDD+), which provides compensation for avoiding deforestation, these countries need an accurate way to calculate stored carbon and to track deforestation and reforestation. “We worked closely with collaborators in 12 countries around the tropics to collect the field data needed to calibrate the satellite measurements and ensure relevance for their national reporting,” said co-author Nadine Laporte, a WHRC associate scientist, who coordinated field measurements in Africa.
“The paper is important for two reasons,” said co-author and WHRC senior scientist Richard A. Houghton. “First, it provides a high-resolution map of aboveground biomass density for the world’s tropical forests. Previous maps were of much coarser resolution and yielded wildly different estimates of both regional totals and spatial distribution. Second, the paper calculates a new estimate of carbon emissions from land-use change in the tropics.”
This was done using the co-location of biomass density and deforestation to assign a more representative carbon density to the forests cleared. Previous estimates used ‘average’ biomass densities that may have biased emissions’ estimates. In short, the approach will lead to better tracking of changes in biomass density resulting from degradation and growth.
The scientists estimated that tropical forests in America store around 118 billion tons of carbon, a fifth more than indicated by previous findings. For the first time in a large-area mapping effort of this kind, an end-to-end approach was constructed quite literally from the ground up, beginning with a pantropical field campaign, relying on the work of scholars in many different countries, and designed for the optimal integration of field and satellite data. The result is a carbon density map for the tropics with a level of consistency and accuracy never before achieved.
“Coupling the Lidar and field measurements is what makes this study and our map so unique, and powerful” stated study co-author and WHRC senior scientist Scott Goetz. “Without measurements from a satellite-based Lidar, a study of this nature would not have been possible. We need that capability going forward.”
The study used field measurements collected across the tropics to calibrate light detection and ranging (LiDAR) satellites models and Moderate Resolution Imaging Spectoradiometer (MODIS) on NASA’s Aqua and Terra to map the carbon densities in the tropics. The carbon density data set is available for download at . Satellite processing algorithms and data are available at https://earthengine.google.org/#state=search&q=tag:mcd43a4
Source: WHRC