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News / Life / Science & Technology

Richland lab finds sawdust may help in Arctic oil spills

Researchers modify the wood to facilitate a burn that removes 90% of oil

By DAN JOLING, Associated Press
Published: December 22, 2016, 5:41am
5 Photos
PNNL microbiologist George Bonheyo displays ordinary sawdust, left, on Dec. 14 and how it appears after being chemically modified to be exceptionally oil-attracting and buoyant, ideal for cleaning up oil spills in the Arctic.
PNNL microbiologist George Bonheyo displays ordinary sawdust, left, on Dec. 14 and how it appears after being chemically modified to be exceptionally oil-attracting and buoyant, ideal for cleaning up oil spills in the Arctic. (Photos by Pacific Northwest National Laboratory/Associated Press) Photo Gallery

ANCHORAGE, Alaska — Federal researchers looking for ways to contain petroleum spills in frigid Arctic waters are investigating whether a powder form of humble sawdust can provide a solution.

Researchers at the Department of Energy’s Pacific Northwest National Laboratory are testing chemically modified wood flour to determine whether it can enhance the burning of crude oil after a spill.

Tests of small batches treated with components of vegetable oil indicate the material will grab onto crude oil and help keep it near the surface. PNNL senior research scientist George Bonheyo, who is also a research professor of bioengineering at Washington State University, calls the material “incredibly buoyant, ice-repelling and water-repelling.”

“It really, really loves oil,” Bonheyo said. “It absorbs at least five times its weight in oil.”

Environmental groups said challenges with cleaning an oil spill are amplified in the Arctic and it’s one of their primary objections to drilling off Alaska’s northern coast. The location is far from ports and other infrastructure taken for granted at drilling sites such as the Gulf of Mexico. Storms are fierce and Arctic waters can be open, frozen or partially covered with ice.

Mechanical recovery has not proven effective because ice can jam skimmers. Researchers at the PNNL lab have focused on burning and bioremediation.

“The point with doing a burn is that it allows you within a matter of minutes to remove upward of 90 percent of the oil from the water,” Bonheyo said.

To burn, he said, untreated crude oil must be fresh and at least 3 mm thick, a little more than two stacked dimes. Early results from lab tests of the chemically treated sawdust indicate the material will help keep an oil slick together in the face of buffeting by wind, waves or ice, Bonheyo said, and allow it to burn in thinner amounts.

“We know we can get below 1 mm,” he said. “We don’t know exactly what the minimum thickness is.”

Crude oil weathers when absorbed by the material but remains buoyant for four months.

“It works very well at holding a spill together. It seems to act kind of like a wick, allowing the volatile, flammable components to rise up to the surface to facilitate an efficient burn,” Bonheyo said.

Bonheyo has a background in research on ship hulls to preventing fouling by organisms. Researchers are looking into adding a bioremediation element to the chemically modified sawdust. Mixtures of organisms adapted for different hydrocarbons, and adapted for different environments, could be added to the wood-based product.

“The idea there is, if any of the oil with the sawdust escaped a burn site, the microbes would be there to consume the escaped oil,” Bonheyo said.

Researchers have conducted burn tests of Alaska North Slope crude oil and Gulf of Mexico crude in warm water at the Navy and Coast Guard Joint Marine Test Facility near Mobile, Ala. Cold water testing is underway. Researchers also are analyzing residue of material that remains after burning.

Researchers during tests have shaken the powdery material onto water surfaces. In the real world, Bonheyo said, it might be dispersed the way materials are distributed by crop dusters.

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