Protecting intact peatlands and restoring degraded ones are crucial steps if the world is to counter climate change, researchers said.

In a study, they said peat bogs, wetlands that contain large amounts of carbon in the form of decaying vegetation that has built up over centuries, could help the world achieve climate goals like the limit of 2 degrees Celsius of postindustrial warming that is part of the 2015 Paris agreement.

But without protection and restoration efforts, some targets for greenhouse gas emissions “would be very difficult or nearly impossible to achieve,” said Alexander Popp, an author of the study, which was published in Environmental Research Letters. Popp is a senior scientist at the Potsdam Institute for Climate Impact Research in Germany.

Peatlands exist around the world, in tropical as well as colder regions. They make up only about 3% of global land area, but their deep layers of peat are practically treasure chests of carbon, overall containing roughly twice as much as the world’s forests. In pristine bogs, that carbon remains soggy and intact. But when a bog is dried out, for agriculture or other reasons, the carbon starts to oxidize and is released as planet-warming carbon dioxide and other greenhouse gases.

That process potentially can continue for centuries. Current estimates are that drained peatlands worldwide emit as much carbon dioxide annually as global air travel.

But dry peat is also a fire risk, and peat fires have the potential to release a lot of carbon very quickly. In September and October 2015, peat fires in Indonesia, where bogs have long been drained for palm oil plantations and other purposes, released more carbon dioxide per day than all the fossil fuels burned in the European Union.

Dried peatlands could be restored by allowing them to become wet again, which would saturate the decaying vegetation and prevent further release of carbon dioxide, and also eliminate the fire hazard. “Rewetting them is really the core for reaching mitigation targets,” Popp said.

Most pathways for countering climate change predict that by the end of this century, land use, which includes forests and agriculture, would be a net carbon sink, meaning it would store more carbon than the amount being released to the atmosphere. That would slow the process of global warming.

But most of those pathways do not take emissions from degraded peatland into account, the researchers said. When they plugged peatland data into their own land-use model, they found that land use would be a net carbon source, releasing more carbon dioxide than was stored.

The researchers then calculated that protecting pristine wetlands and rewetting about 60% of the degraded ones would reverse that, making land use a net sink again. “Despite covering a small area, they really pack a carbon punch when it comes to carbon storage in ecosystems,” said Mike Waddington, a peat researcher at McMaster University in Hamilton, Ontario. “They are really important in global climate regulation.”

He said the study made an important point: In current pathways for changing land use to aid the climate, through planting more trees or other measures, peatlands are often considered expendable. “When we think about storing carbon in ecosystems, it’s almost always about planting trees,” Waddington said. There’s often tremendous pressure to plant trees in drained peatlands, he said, but that’s the wrong choice given the carbon-storing ability of an intact bog.