Stanford researchers have developed a gel-like fluid to prevent wildfires

Scientists and engineers worked with state and local agencies to develop and test a long-lasting, environmentally benign fire-retarding material. If used on high-risk areas, the simple, affordable treatment could dramatically cut the number of fires that occur each year.

A preventive treatment developed by Stanford researchers could greatly reduce the incidence and severity of wildfires. The approach, outlined Sept. 30 in Proceedings of the National Academy of Sciences, involves an environmentally benign gel-like fluid that helps common wildland fire retardants last longer on vegetation.

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Stanford Woods Institute for the Environment

A new technology developed by Stanford engineers promises a way to prevent a significant percentage of wildfires and drastically reduce the cost of fighting them.

Applied to ignition-prone areas, these materials retain their ability to prevent fires throughout the peak fire season, even after weathering that would sweep away conventional fire retardants. By stopping fires from starting, such treatments can be more effective and less expensive than current firefighting methods.

“This has the potential to make wildland firefighting much more proactive, rather than reactive,” said Eric Appel, the study’s senior author and an assistant professor of materials science and engineering in the Stanford School of Engineering. “What we do now is monitor wildfire-prone areas and wait with bated breath for fires to start, then rush to put them out.”

A century of fire suppression plus hotter, drier weather has intensified the destructive power of wildfires and lengthened the season of threat. While the 2019 season has been relatively calm in the West so far, the past two years have brought four of the 20 largest and eight of the 20 most destructive wildfires in California’s history. Across the country, federal firefighting costs in 2018 came to more than $3 billion – the highest total ever.

Long-lasting, environmentally benign

Wildfires are a critical part of some ecosystems, but the vast majority in the U.S. are human-caused. Many of them originate in the same hotspots, such as roadsides, campgrounds and remote electrical lines, time after time. Treating these areas prophylactically could provide a highly targeted approach to wildfire prevention, but, until now, long-lasting and environmentally benign materials have not been available.

Under the supervision of CalFire, the researchers performed test burns on a grassy roadside area near San Luis Obispo, California, to gauge the effect of a fire-retarding hydrogel. The images above show untreated (left) and treated (right) plots shortly after fire ignition. (Image credit: Eric Appel)

Aside from clearing and burning potential fuels, wildfire management generally revolves around fire suppressants and retardants, with many suppressants used as short-term retardants. To fight active fires, crews use suppressants, such as gels that carry water and superabsorbent polymers found in diapers. These gels are frequently used as short-term retardants on buildings in the path of encroaching fires, but they lose effectiveness once the water entrapped in them evaporates – something that often occurs in less than an hour during normal wildland fire conditions.

The most widely deployed commercial wildland fire retardant formulations use ammonium phosphate or its derivatives as the active fire-retarding component. However, these formulations only hold retardants on vegetation for short periods of time, so they can’t be used preventively. By contrast, the Stanford-developed technology – a cellulose-based gel-like fluid – stays on target vegetation through wind, rain and other environmental exposure.

“You can put 20,000 gallons of this on an area for prevention, or 1 million gallons of the traditional formulation after a fire starts,” said study lead author Anthony Yu, a PhD student in materials science and engineering at Stanford.

Complete fire prevention

Map of California displaying wildfires between Jan. 1, 2009, and Dec. 31, 2018. Fires that started at high-risk locales (roadsides and utilities infrastructure) are highlighted in red. Fires that started in all other locales are shown in gray. Tier 2 and Tier 3 fire-threat regions, as designated by CalFire, are highlighted in orange and dark orange. (Image credit: Eric Appel)

The researchers have worked with the California Department of Forestry and Fire Protection (CalFire) to test the retardant materials on grass and chamise – two vegetation types where fire frequently starts. They found the treatment provides complete fire protection even after half an inch of rainfall. Under the same conditions, a typical commercial retardant formulation provides little or no fire protection. The researchers are now working with the California Department of Transportation and CalFire to test the material on high-risk roadside areas that are the origin of dozens of wildfires every year.

“We don’t have a tool that’s comparable to this,” said Alan Peters, a CalFire division chief in San Luis Obispo who monitored some of the test burns. “It has the potential to definitely reduce the number of fires.”

The Stanford-developed treatment contains only nontoxic starting materials widely used in food, drug, cosmetic and agricultural products. The unique properties of these gel-like retardant fluids allow them to be applied using standard agricultural spraying equipment or from aircraft. While it washes away slowly, providing the ability to protect treated areas against fire for months, the materials eventually degrade.

“We hope these new materials can open the door to identifying and treating high-risk areas to protect people’s lives and livelihoods,” said Appel.

Appel is also an affiliate of the Stanford Woods Institute for the Environment. Stanford co-authors include postdoctoral researcher Hector Lopez Hernandez; graduate students Andrew Kim, Lyndsay Stapleton and Doreen Chan; and Craig Criddle, a professor of civil and environmental engineering in the Stanford School of Engineering, a senior fellow at the Woods Institute for the Environment, director of Stanford’s Codiga Resource Recovery Center, a member of Bio-X and an affiliate of the Precourt Institute for Energy. Additional co-authors are from California Polytechnic State University, San Luis Obispo, and the Desert Research Institute.

Funding was provided by the Eastman Kodak Company, the National Science Foundation and the Stanford Woods Institute for the Environment.

Yu and Appel are inventors on a patent describing the technology reported in this study.

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