CFL Blog’s Best of 2016: Recalculating the Cost of Invasive Species

As the year winds to a close, we’re taking a look back at some of the the CFL’s most popular blog posts from 2016. Here’s one originally published on March 21st about our researchers calculating the cost of a tiny invasive species and finding a very big impact.

MADISON – A new study shows we’ve dramatically underestimated the economic and ecological impact of invasive species in the Great Lakes. In fact, according to researchers at the University of Wisconsin-Madison, a single non-native species in a single inland lake has racked up $80-to-$163 million in damages.

Jake Walsh (right), graduate researcher for the Center for Limnology, and undergraduate Carly Broshat (left) use plankton nets to collect water samples of spiny water flea, an invasive species of zooplankton, in Lake Mendota. (Photo by Bryce Richter / UW-Madison)
Jake Walsh (right), graduate researcher for the Center for Limnology, and undergraduate Carly Broshat (left) use plankton nets to collect water samples of spiny water flea, an invasive species of zooplankton, in Lake Mendota. (Photo by Bryce Richter / UW-Madison)

The findings suggest a need to recalculate the cost of invasive species.

“Our study indicates that previous attempts to put a price tag on invasive species impacts haven’t come close to the true cost,” says Jake Walsh, a Ph.D. candidate at the UW Center for Limnology and lead author of the report, published in the Proceedings of the National Academy of Sciences. (link here)

The study might also inform the conversation about costs and benefits of the Great Lakes shipping industry. For decades, oceangoing ships have brought tons of cargo and tens-of-millions of dollars into the Great Lakes economy each year. But that man-made connection between the Great Lakes and the Atlantic Ocean has also helped bring in more than 180 non-native species.

Most studies, Walsh says, have focused only on invasive species that live in the five Great Lakes and looked just at direct costs of managing them – like the $20 million spent each year to poison invasive sea lamprey.

Instead, Walsh and his colleagues turned their attention to secondary invasions, or places where invasive species have moved since their introduction to the Great Lakes. The researchers also added “ecosystem services,” the benefits that humans derive from our natural resources, to the equation.

For example, Lake Mendota, in Madison, Wisconsin, is essential to both the local economy and residents’ quality of life – supporting pursuits like fishing, boating, swimming and recreation along its shores. Clear, clean water is the key ingredient to all of these ecosystem services.

Since 2009, the spiny water flea has triggered a massive loss of water quality in Lake Mendota. Photo: Steve Carpenter
Since 2009, the spiny water flea has triggered a massive loss of water quality in Lake Mendota. Photo: Steve Carpenter

However, since at least 2009, Lake Mendota has been invaded by a tiny, voracious zooplankton called the spiny water flea. Originally from Russian lakes, the invader made its way to the Great Lakes in the ballast water of oceangoing cargo ships, historically a major vector of Great Lakes invasive species introductions. The spiny water flea then moved inland in boats or bait buckets and now feasts on a native species of zooplankton called Daphnia pulicaria.

Left to their own devices, says Walsh, daphnia help “clean” the lake by eating huge amounts of algae – so much algae, in fact, that they create clear water. Today, however, Lake Mendota’s daphnia are falling prey to the spiny water flea before they can take their toll on algae.

Complicating matters is agricultural fertilizer that runs into the lake. This fertilizer contains lots of phosphorus, which promotes the growth of algae just as well as corn or soybeans. These high-fertilizer, low daphnia conditions add up to a dramatic decline in water clarity and a sharp rise in algal blooms.

Currently, there is no way to rid a lake of billions of nearly microscopic zooplankton short of poisoning the entire water body of water. But there are land-use practices and technologies available to reduce phosphorus runoff.

Through statistical modeling, the researchers determined that it would take a 71 percent reduction of phosphorus to return Lake Mendota’s water quality to pre-invasion conditions; stemming that flow comes at a steep price – anywhere from 80-to-163 million dollars.

It’s a big number, Walsh concedes, but “it gives us a clearer understanding of the ‘true cost’ of invasive species.”

While only a fraction of the 180 species that have entered the Great Lakes have become nuisance enough to be labeled “invasive,” their collective impact is staggering says Walsh. “There are hundreds of billions of dollar’s worth of damages we can account for right now. If you add in invasive species’ impact on ecosystem services and look at secondary invasions, then that number is likely to be trillions,” he says.

In spite of the staggering sticker shock, Walsh sees a silver lining. Many invasive species eradication or control efforts have been deemed too expensive to entertain researching or implementing them. But, Walsh says, if the price of not fighting these invasions is as high as his study indicates, “maybe we have a much bigger budget than we thought we did.”

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— Adam Hinterthuer (608) 890-2187, hinterthuer@wisc.edu