By Yiyuan Jasmine Qin and Todd Gartner Drought in Sao Paulo. Flooding in the Himalayas. And pollution in Sumatra. These three distinct water crises have a common cause—degradation in forests. That’s because upstream forests, wetlands and other “natural infrastructure” play a critical role in supplying clean water downstream. They stabilize soil and reduce erosion, regulate water flow to mitigate floods and droughts, and purify water. Yet the world’s major watersheds lost 6 percent of their tree cover on average from 2000-2014, putting citizens at risk of losing their water supplies.
Global Forest Watch (GFW) Water, a global mapping tool and database launched today, examines how forest loss, fires, unsustainable land use and other threats to natural infrastructure affect water security throughout the world. GFW Water provides data sets, statistics and risk scores for all of the world’s 230 watersheds, areas of land where all of the water drains to a common outlet such as a river. Users can drop a pin anywhere to learn about the risks to the water supply near them, and find resources on how investing in natural infrastructure protection can help alleviate these threats.
- Downstream utilities, municipalities, businesses and others who make infrastructure investments can identify risks and explore natural infrastructure options and find information to improve operations and protect water at a lower cost.
- Finance and development institutions can gather data, explore trends and gain insights about the regions they support to develop a pipeline of investable opportunities to enhance water security and bolster economic development.
- Researchers and civil society can use data to support their projects and find the information needed to advance their research and campaigns to protect watersheds.
Findings from GFW Water reveal some of the watersheds most threatened by forest loss, fires and erosions:
Recent Forest Loss in Sumatra, Indonesia Watershed
As forests are cut down or converted to other land uses, their ability to regulate flow and purify water diminishes, putting communities at risk of flood, drought, higher water treatment costs and greater incidence of drinking water contamination. The watershed of Sumatra, Indonesia experienced the most forest loss from 2000-2014, losing more than 22 percent of its forest cover (8 million hectares, or an area about the size of South Carolina). Research shows that agricultural expansion, logging and infrastructure extension as a result of expanding global markets for pulp, timber and oil palm are among the major drivers. Forest clearing in the region has intensified floods, landslides, fires and water pollution.
Natural infrastructure approaches can mitigate and prevent further damage in watersheds like Sumatra. Establishing conservation zones, engaging in agroforestry and other sustainable forestry practices and regulating road development can help.
Historical Forest Loss in Krishna, India Watershed
Forest loss that took place decades ago—prior to 2000— also leads to changes in water flow, higher sediment levels and more, and the impacts are often more uncertain compared to recent forest loss.
According to GFW Water, watersheds lost more than half of their forests prior to 2000. The watershed of Krishna, India was once covered by forests, but fewer than 3 percent of these trees remain today as a result of urbanization and cropland expansion. Communities in the area suffer from frequent droughts and floods, as well as high levels of water pollution from agricultural runoff. Sedimentation is a recurring challenge to reservoirs and dams. Planting new seedlings in deforested areas, enhancing natural forest generation, and integrating trees with crops and ranchlands could help watersheds like Krishna.
Erosion in the Philippines Watershed
Erosion is a significant problem that affects both water quality and quantity. High erosion deteriorates water quality and reduces reservoir capacity, increasing the cost of water treatment and the risk of contamination. High erosion risk is usually linked to erodible soil, intense rainfall, steep topography and conversion of forest and other natural lands to pasture, cropland and more.
The Philippines watershed faces some of the highest erosion rates as a result of highly erodible soil, a long and intense rainy season, mountainous landscapes and expansive agriculture. The region frequently suffers from landslides. In 2006, following days of heavy rain, a massive mudslide occurred in the province of Southern Leyte, causing widespread damage and loss of life. Planting or maintaining vegetation along roads and waterways to capture sediments and pollutants; creating barriers on steep slopes to slow soil movement; and reducing the amount of pesticides, fertilizers, animal waste and other agricultural products entering waterways can help watersheds threatened with erosion.
Fires in Angola, Coast Watershed
Fires are a common disturbance in some forests, damaging both watersheds and communities nearby. High intensity or large fires can increase agricultural runoff, cause erosion and kill trees, all of which can negatively impact water quality and flow.
In the watershed of Angola, Coast, NASA satellites detected more than 130,000 fire occurrences annually for the past 10 years. Over the past 24 hours alone, there were 267 fire alerts (data retrieved on August 29, 2016). This is a common occurrence in western Africa as farmers often use fire to fertilize soil and clear the field of unwanted vegetation. In areas like western Africa where fires are deliberately set to manage land, alternative solutions such as growing crops in between woody plants can help prevent unwanted vegetation while bringing other benefits like improved crop production and erosion control. In regions like California where dense forests fuel catastrophic wildfire, mechanical forest thinning and controlled burns can reduce wildfire severity and related sediment and ash pollution. In the face of growing water challenges, we need cost-effective, sustainable solutions. Sometimes investing in nature is the best way to solve complex problems. To learn more about the methodology behind GFW Water, please refer to Global Forest Watch Water Metadata Document.