Researchers study a core sample from the deep layer of peat (Credits: Professor Charles Harvey, SMART)
Satellite mapping through InSAR remote sensing of subsidence helps to measure how much carbon has been released into the atmosphere from peatland drainage and drying
Peatlands are extremely carbon-rich ecosystems essential to planet health and biodiversity
The InSAR approach detects changes in surface elevation of peatlands, which can be directly linked to the amount of carbon emissions
Remote sensing using satellite data allows scientists to get accurate measurements of peatland subsidence without having to make challenging treks through peatlands
The process can be implemented across various forms of land use and vast areas of peatland, and reveals how widespread peatland drainage really is
Researchers from Singapore-MIT Alliance for Research and Technology (SMART), MIT’s research enterprise in Singapore, and Massachusetts Institute of Technology (MIT) have published a new satellite-based study that reveals the severity of peatland damage in Southeast Asia, using a unique approach that allows remote monitoring of subsidence and carbon dioxide emissions in tropical peatlands. About 60% of the world’s tropical peatlands are found in Southeast Asia, but the drying of these swamplands for farming and other practices have plagued the region with violent forest fires and haze each year.
Peatlands are naturally occurring wetlands that are extremely carbon-rich environments, which when dried or drained become highly flammable and can release their accumulated carbon even when unburned. On top of causing forest fires and Southeast Asia’s infamous annual haze, the carbon emissions from damaged peatlands add significantly to the world’s greenhouse gas emissions. The new study utilises their unique Interferometric Synthetic Aperture Radar (InSAR) approach that uses satellite data to detect changes in surface elevation in tropical peatlands.
Detailed measurements of the degree of subsidence over an area of 2.7 million hectares, 10% of Southeast Asia’s peatland area mostly in Malaysia and Indonesia, were gathered using InSAR remote sensing. Over 90% of the area studied was found to be subsiding, at an average of 2.24cm over a year, demonstrating that subsidence is not limited to plantations.
The findings are explained in a paper titled “Widespread subsidence and carbon emissions across Southeast Asian peatlands” recently published in the prestigious journal Nature Geoscience. It confirms that long-term peat oxidation is a large source of CO2 emissions, consistent with previous regional estimates. Long-term subsidence rates are as high as 5 cm yr−1 in ground-based measurements, and if maintained, could result in flooding within a few decades. Until now, it has been an arduous process to measure the drainage and drying of peatlands, involving difficult treks through the dense swamplands, and dependent on local guides who know their way around.
With the InSAR remote sensing approach, the researchers were able to gather detailed satellite measurements of the degree of subsidence in the peatlands. This also provides a measure of carbon emissions from peatland drainage and drying, as the amount of land that has subsided over the years can be directly linked to how much carbon has been released into the atmosphere. “Thirty years ago, or even 20 years ago, this land was covered with pristine rainforest with enormous trees,” says Professor Charles Harvey, Principal Investigator at SMART and Professor at MIT’s Department of Civil and Environmental Engineering.
He says that was still the case when he began doing this research in Southeast Asia over a decade ago. “Unfortunately in 13 years, I've seen almost all of these rainforests removed. There's almost none at all anymore, in that short period of time.” While some analysts previously thought making way for palm oil plantations was the major reason behind peatland loss, the new study shows this accounts for only 27% of the subsidence. The rest is due to drainage for a range of reasons including small-scale agriculture, creating canals to float timber out of the forests, digging of drainage ditches, or preparing land for failed large scale rice-farming experiments.
“Peatlands are really unique and carbon-rich environments and wetland ecosystems,” says Alison Hoyt, MIT PhD ‘17 and Postdoctoral Researcher at the Max Planck Institute for Biogeochemistry. “This work represents the first time that we actually can make measurements across many different types of land uses rather than just plantations, and across millions of hectares.”
By allowing remote tracking of many different types of land use across vast areas, the satellite-based InSAR remote sensing approach allows scientists to understand just how widespread the draining of peatlands has been.
This research was supported by the National Research Foundation Singapore under its Campus for Research Excellence and Technological Enterprise (CREATE) programme, SMART, the U.S. National Science Foundation, and MIT’s Environmental Solutions Initiative.