How
plastic waste moves in the environment
Washington State
University
A Washington State
University researcher for the first time has modeled how microplastic fibers
move through the environment.
The work, published in
the November print issue of the journal Advances in Water Resources,
could someday help communities better understand and reduce plastics pollution,
which is a growing problem around the world.
Millions of tons of plastic
waste in tiny microscopic pieces are bobbing around the world's oceans and are
finding their way into soil, sediments and freshwater.
Plastic debris comes from many sources including synthetic clothing fibers, cosmetics, packaging and industrial processes. These plastic bits often end up in the oceans, harming the marine life that eats them.
Plastic debris comes from many sources including synthetic clothing fibers, cosmetics, packaging and industrial processes. These plastic bits often end up in the oceans, harming the marine life that eats them.
Researchers have
studied and measured microplastics in a variety of environments, but Nick
Engdahl, an assistant professor in the Department of Civil and Environmental
Engineering, is the first to model how the synthetic fibers move.
"I wanted to know whether they keep moving and spreading or if they just accumulate in one place," said Engdahl, who has studied the movement of a variety of contaminants in the environment.
He used a novel
physics-based approach to simulate the movement of microplastic fibers,
specifically. These synthetic fibers in clothing are created during their
manufacturing process.
"Every time you walk or rub against something your clothes are shedding fibers," said Engdahl.
The microfibers, which are mainly released when clothes are washed, end up in wastewater plants, where a significant proportion pass through water filtration systems. Even the ones that are filtered end up in the sewage sludge that can be applied to farm soils as fertilizer or dumped in landfills.
Engdahl found that the
length of the fibers and the speed of water that they're floating in determined
whether they settle in soil or continue moving in the environment.
He also found that the movement of shorter microplastic fibers was complex, and that they moved faster than dissolved substances in the water.
He also found that the movement of shorter microplastic fibers was complex, and that they moved faster than dissolved substances in the water.
Engdahl is working to
verify and refine his model against direct observations of microplastic fiber
movement in a lab. He also plans to measure the fibers in a wastewater
treatment facility.
"The more data I
can get from the real world, the more accurately I will be able to see if these
things move around or stay put and pile up," he said. "This will help
us more accurately measure their environmental impact, which is largely unknown
right now."