“People want to blame the rain, but this is mostly us…It’s a manmade disaster.”
Robert Criss, PhD, professor of earth and planetary sciences in Arts and Sciences at Washington University in St. Louis, says the extreme flooding on Meramec and Mississippi rivers in late December cannot be blamed solely on 3-day rains.
A news release by Washington University in St. Louis explains that recent developments along the Meramec and its tributaries increased flood levels dramatically during the December 2015 flood disaster. These developments had destroyed riparian borders so that they became torrents after rain but no longer flowed continuously.
News Report by Washington University in St. Louis, 05 February 2016
At the end of December 2015, a huge storm named “Goliath” dumped 9-10 inches of rain in a belt across the central United States, centered just southwest of St. Louis, most of it in a three-day downpour.
The rain blanketed the Meramec Basin, an area of 4,000 square miles drained by the Meramec River, which enters the Mississippi River south of St. Louis.
The Meramec’s response was dramatic. Gauging stations recorded a pulse of water that grew as it traveled down the main stem of the Meramec River, setting all-time record highs in the lower basin in the Missouri cities of Eureka, Valley Park and Arnold.
While extraordinary rain drenched the entire Meramec Basin, only 5 percent of the Mississippi River’s giant watershed above St. Louis was so affected. Yet only a day after the flood on the lower Meramec peaked, water levels on the Mississippi at St. Louis were the third-highest ever recorded. A few days later, record flood stages were recorded downstream at Cape Girardeau, Mo., and Thebes, Ill.
Why was the flooding so bad? Most news reports blamed it on the heavy rain, but Robert Criss, PhD, professor of earth and planetary sciences in Arts & Sciences at Washington University in St. Louis, said there was more to the flood than the rain.
“I think there was significant magnification of the flood levels on the Meramec by recent developments near the river,” he said. “Sure it rained a lot, but what happened here cannot be explained by the rainfall alone.”
The flood on the middle Mississippi River, in turn, was remarkable for its short duration and the time of year. “It was essentially a winter flash flood on a continental-scale river,” Criss said. “The Mississippi has been so channelized and leveed close to St. Louis that it now responds like a much smaller river.”
In the February issue of the Journal of Earth Science, Criss and visiting scholar Mingming Luo of the China University of Geosciences in Wuhan, China, take a close look at data for the New Year’s flood, treating it as a giant natural experiment that allowed them to test their understanding of changing river dynamics.
“Flooding is becoming more chaotic and unpredictable, more frequent and more severe,” Criss said. “Additional changes to this overbuilt river system will only aggravate flooding.
“In the meantime,” he said, “inaccurate Federal Emergency Management Agency flood frequencies based on the assumption that today’s river will behave as it has in the past greatly underestimate our real flood risk and lead to inappropriate development in floodways and floodplains.”
What happened at Valley Park and why?
The prior flood of record in most of the lower Meramec Basin occurred on Dec. 6, 1982, Criss said. Given that the 1982 flood, like the 2015 flood, was a winter flood during an El Niño event, they should have been similar. Criss thought it would be revealing to compare them.
When he did this, he discovered that the peak flood stage at Valley Park in 2015 was three-feet higher than it would have been had the river responded as it had in 1982, and more than a foot higher upstream from Valley Park at Eureka in 2015 than in 1982.
What had happened at Valley Park between 1982 and 2015? A three-mile-long levee had been built next to the river; a landfill partly in the river’s floodway (as defined in 1995) had expanded; parts of the floodplain had been built up with construction fill; and development along three small tributaries of the Meramec had destroyed riparian borders, so that they became torrents after a rain but no longer flowed continuously.
The record high water levels on the Meramec were associated with these developments, Criss said. “The biggest jump in the flood stage was next to the landfill in the floodway and to the new levee, which restricted the effective width of the floodway and ‘100-year’ floodplain by as much as 65 percent.”
He drives home the point by breaking the flood data into two chunks and looking at the earlier half separately from the later half. When he does this, it becomes apparent the river is becoming more chaotic and unpredictable and that floods are more frequent, higher and more damaging than they once were.
As the New Year’s flood demonstrates, when we assume an unchanging river, we greatly underestimate our flood risk, he said. “The St. Louis levees protected us from the 1993 flood, considered a 330-year event,” he said. “But if a real ‘200-year’ flood occurred on today’s river, the structures protecting St. Louis would be overtopped.
“The heavy rainfall was probably related to El Niño, and possibly intensified by global warming. But new records were set only in areas that have undergone intense development, which is known to magnify floods and shorten their timescales.
“People want to blame the rain, but this is mostly us,” Criss said. “It’s a manmade disaster.”
During the New Year’s flood, roughly 7,000 buildings near St. Louis were damaged, two interstate highways were closed for several days, the community of Valley Park was evacuated, and two Metropolitan Sewer District plants were swamped so that sewage was dumped directly into the water. The flood killed more than 20 people in Missouri and Illinois, caused several hundred million dollars of damage, and left millions of tons of debris in its wake.