91吃瓜

For decades, global efforts to combat climate change and protect biodiversity have relied on a high-tech promise: that satellite-derived maps can tell us exactly where the world's forests are.

But a new study from the University of 91吃瓜 reveals that these digital baselines are often in sharp disagreement, creating confusion that threatens to undermine effective climate funding and international development efforts. Because these maps determine everything from carbon storage estimates to the enactment of conservation policies, even small discrepancies can have serious consequences for both people and the planet.

The , co-authored by the Coyle Mission Collegiate Associate Professor at 91吃瓜鈥檚 reveals major differences among the world鈥檚 most widely used forest datasets. When comparing eight of the most popular datasets, the researchers found that their identification of forest locations concurred only 26 percent of the time.

The problem stems from how different researchers define 鈥渇orest鈥� and the digital technology they use to view forests, said Miller, a core faculty affiliate of the Keough School鈥檚 Pulte Institute for Global Development.

鈥淲hen land is viewed from the sky, it鈥檚 difficult to know at a global scale whether something is a forest or not,鈥� he said. 鈥淪ome might consider a small patch of trees to be a forest, but for others only a large, dense area of trees will count.鈥�

The study found that the discrepancy among datasets creates major uncertainty, sometimes by a factor of 10. For example, some maps might count a savanna interspersed with trees as forest based on a 10 percent canopy cover threshold, while others require 50 percent. These small definitional differences can flip millions of hectares from 鈥渇orest鈥� to 鈥渘on-forest鈥� in an instant.

The researchers used case studies from Brazil, India and Kenya to show how these digital maps affect human lives and global policy challenges. In India, for example, the estimated number of people living in poverty near forests fluctuated from 23 million to 252 million depending solely on which map was used.

A framework for the future

To help policymakers, journalists and others navigate this 鈥渄igital wilderness,鈥� the researchers created a flowchart to help non-experts determine which data sets are most appropriate for their specific region or goal. Miller said that future work should integrate hybrid data that combines on-the-ground views with satellite data.

鈥淏y bridging the gap between satellite technology and on-the-ground reality, we can provide more accurate, inclusive data that truly supports both the planet and the people who protect it,鈥� he said.

Real-world stakes

Miller warned that if forest definitions continue to vary, countries could overestimate 鈥� or dangerously underestimate 鈥� their carbon sequestration potential.

鈥淚t could make a real difference in climate finance commitments and how much vulnerable communities gain,鈥� he said.

Co-author Sarah Castle of the University of Wisconsin鈥揗adison emphasized that accurate data is a prerequisite for trust in global markets for environmental goods like carbon and timber and underscored the need for better standardization and transparency so the global community can agree on common reporting metrics.

鈥淚f we cannot establish a reliable baseline for forest area, it undermines trust in nature-based markets and makes it nearly impossible to accurately measure the role forests play in supporting people鈥檚 lives and livelihoods,鈥� Castle said.

In addition to Miller and Castle, the study was co-authored by Peter Newton of the University of Colorado Boulder, Johan A. Oldekop of the Global Development Institute and Kathy Baylis of the University of California, Santa Barbara.

Funding for the study was provided by and the Keough School鈥檚 through the .

Originally published by Ren茅e LaReau at on Jan. 12.

Contact: Tracy DeStazio, associate director of media relations, 574-631-9958 or tdestazi@nd.edu