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Life after lava

The surprising biodiversity of Mount St. Helens post-eruption
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High Country News

Editor's Note: The Pacific Ring of Fire is a 40,000 kilometre-long belt of geological features looping around the Pacifc Ocean, created by the continual movement of the earth's tectonic plates. It's comprised of volcanic zones and oceanic trenches stretching from the northeast coast of New Zealand to the Kamchatka peninsula of Russia in the north; across the Aleutians to Alaska and back south again along the coast of North and South America to the southern tip of Chile. It affects New Zealand (earthquake measuring 6.3 on the Richter Scale on Feb. 22, with almost 350 deaths) and Japan (earthquake on Mar. 11 measuring 9.0 unleashes a tsunami, up to 30,000 killed). In March 2010, Chile experienced a pair of strong quakes (8.8 and 6.3) that unleashed a tsunami that left hundreds dead and thousands more homeless.

The simple explanation for all this shaking is that the tectonic plates are continually in motion, pulling, pushing and shifting around one another. When one plate pushes up against another, the pressure builds until something has to give. That pressure pushes up mountains, but it can also lead to quakes and the formation of volcanoes - which often take the appearance of mountains, with a recognizable conical shape.

There is evidence of volcanism all over the coast of B.C. and close to Whistler as part of the Garibaldi Volcanic Belt (which is part of the larger Cascade Volcanic Arc).

Right now the main risks seem to be landslides and flooding when loose volcanic materials slump into waterways and allow water to build up behind them. Just last summer, Pemberton was put on alert after heavy rains triggered a major landslide in the still volcanic Meager area, creating a natural dam with a massive lake behind it. The dam eventually disintegrated, but the worst-case scenario was a sudden release of a large amount of water.

For years B.C. has also been preparing for a large earthquake that geologists are certain is coming, and that some believe is probably overdue.

While it's possible that some moderate quakes could occur in the Georgia Strait between Vancouver Island and the mainland, the real risk is for a quake up to 9.0 - the size of the one that hit Japan on Mar. 11 - off the west coast of Vancouver Island.

Generally speaking, most of the volcanoes in the region are dormant and pose little risk.

Volcanism in the region is the result of the Pacific Oceanic Plate pushing the Juan de Fuca Plate under the North American Plate, which causes pressure to build up in the earth's crust. That pressure bubbles up to the surface, following fractures and volcanic vents, until we see an eruption.

The most spectacular eruption in recent history was Mount St. Helens on the Olympic peninsula of Washington State. Geologic pressures built up within the mountain, which bulged, cracked and broke apart the north face of the mountain. The sudden change in pressure led to an explosion, which ejected rock, ash and lava into the atmosphere.

The situation in Japan is a sobering reminder that the south coast of B.C. is part the Pacific Rim of Fire, and that earthquakes and volcanoes are a natural part of this geological cycle. We get mountains next to beaches, but also a legacy of natural disasters.

If Mt. St. Helens is any indication, these disasters are only blips in the ecological record. Life always returns.

 

The hummocks of Mount St. Helens' northern slope look decidedly haphazard. Barren, knuckle-shaped hills alternate with groves of red alder. A straggly willow grows from a mound of rocky soil. Patches of yellow moss are broken by wild strawberry blossoms and the occasional flare of red paintbrush.

The effect is unsettling, as if the landscape were the result of a giant habitat-components lottery.

Seated on the banks of a small pond in mid-May, ecologist Charlie Crisafulli stuffs a frog into a sandwich bag. "Trap three," Crisafulli says to a field assistant taking notes. He holds a ruler to the animal and gently pinches it so its limbs splay out. "Length of 152 (millimeters), and snout, vent, 74 (mm). We have a bulbous male."

Crisafulli releases the frog into the murky water with a plop. Twenty-four hours ago, his team planted funnel traps in six different ponds; now, they're cataloguing the captured amphibians.

In the 31 years since a volcanic eruption obliterated the mountain's forests and showered its lakes with burning debris, amphibians have returned with astounding speed. The Western toad and Pacific treefrog led the way, and by 1990 all the pond-dwelling amphibians that typically inhabit southern Washington's Cascade Range were somewhere on the volcano.

Part of that abundance is due to the post-eruption environment: It's taken longer for predators to return and there's less competition for habitat. It also helps that the hummocks region lies within the Mount St. Helens National Volcanic Monument, a 110,000-acre (445-square kilometre) area around the summit where the landscape has been left mostly untouched. It's essentially a living laboratory of how an ecosystem recovers without human tinkering.

That's the theory, anyway. But the monument has never truly stood in isolation; its borders are dotted with timber farms and its rivers flow past a fish hatchery and several towns. As a result, human-influenced changes have sometimes clashed - and blended - with the mountain's "natural" recovery. A push here, a snip there, and what has emerged is a landscape of surprises, one that blurs the line between expected regrowth, deliberate engineering and random chance.

 

In 1979, St. Helens was postcard-perfect, a snow-capped cone rising 9,700 feet (2,800 metres) above southern Washington. Over 500,000 people visited that year to hike, hunt, camp and fish. Farther downslope, the mountain hosted a thriving timber industry.

The earthquakes began in March of 1980. For two months they rocked the mountain, as magma pushed its northern slope outward. Then, on May 18, that slope collapsed in the biggest landslide in recorded history. A mixture of steam, rocks and hot gas exploded sideways from the crater, charging down the mountainside and prompting huge mudflows as it melted ice and snow.

The mountain's lush, coniferous forests were flattened. Fifty-seven people died, scientists and holdout resident ignoring the evacuation order, and nearby communities feared further damage from subsequent landslides. Many thought it would be decades before the mountain resembled its former self. But the volcano was also a scientific gold mine, and in 1982, Congress passed the National Volcanic Monument Act. Everything within the new monument - which encompassed some of the worst-hit federal, state and private lands - became Forest Service land, necessitating complex land swaps.

Although the monument is open to the public, mining and tree harvesting were banned within its borders, along with off-road motor vehicles. Some 25 per cent of the monument received further protection as a research area where visitors are restricted to specific trails. So it was that the monument became a haven for science, education and recreation, allowing "geologic forces and ecological succession to continue substantially unimpeded."

Today, the contrast between the monument and its surroundings is absolute. Thick conifers turn the slopes of bordering Weyerhaeuser lands a uniform dark green; metal signs along the road read Planted 1992; Planted 1986; Planted 2001. Meanwhile, the monument is a checkerboard of habitats, each marking a different stage of ecological recovery: dazzling fields of wildflowers, a barren pumice plain, saplings in the hummocks.

For Crisafulli, it's this diversity that makes the monument special: Because of the sheer variety of available niches, it may now be more biologically diverse than before the eruption. That's partly why Crisafulli has worked on the mountain since 1980, first as a graduate student monitoring the return of small mammals, then later as an ecologist with the U.S. Forest Service.

 

It's late morning, and Crisafulli runs around his crew's loose collection of tents, stuffing waders and notebooks into a dry bag. He has the beard and baseball cap typical of many field scientists; a long ponytail hangs down his back.

As we hike toward a set of ponds through morning drizzle, Crisafulli launches into tour-guide mode. That yellowish moss is Racomitrium canescens. Those green-leafed trees are red alders, the yellow-leafed ones cottonwoods. Waist-high shrubs with crimson branches are willows. "We're really walking on the guts of St. Helens," Crisafulli explains. Every rock and handful of dirt that forms these hummocks came from the landslide that preceded the eruption.

As water collected in the hollows between hummocks, 150 new ponds formed. Some were no more than large puddles. Others, like Coldwater Lake, filled entire valleys.

Thirty eventually washed out or overflowed. Such change could be expected, explains Monument Manager Tom Mulder. "We're learning what Mother Nature does" when left alone. Ultimately, however, fears of flooding forced officials to put public safety before the monument's natural processes.

 

Before 1980, Spirit Lake, on the north face of the mountain, held Pacific salmon that had swum upstream through the Columbia, Cowlitz and Toutle rivers. But the landslide buried the outlet from Spirit to Toutle. As lake levels rose, officials worried that the natural dam could catastrophically breach, setting off a chain reaction in dozens of other ponds and sending a massive flood down the Toutle, straight into Castle Rock, Longview and Kelso - downstream communities with a combined population of 50,000.

So the Army Corps of Engineers built a mile-long concrete tunnel within the monument, allowing Spirit Lake to discharge into South Coldwater Creek, which flows west into Coldwater Lake. There, the Corps was forced to build another drainage outlet - this time a cobble-lined channel - connecting Coldwater Lake to Coldwater Creek.

The tunnel ensured that fish would never again find their own way to Spirit Lake, but it pales in comparison to what happened next. Landslide debris had increased the sediment load on the North Fork of the Toutle River more than a hundredfold, and the Corps feared it would raise riverbeds and facilitate future flooding. Since the agency is charged with flood protection, it built a sediment-retention structure - a dam that slows the river so sediment can settle while clear water passes downstream. Although the structure lies a few miles outside the monument, it prevented migratory fish from spawning upstream.

That was the start of fish trucking. Since 1989, Washington Department of Fish and Wildlife has trapped fish below the dam and transported them to upstream tributaries. The goal is to re-establish historic runs of native fish, including coho salmon and steelhead (a form of migratory rainbow trout) which support sport and commercial fisheries. Both species are also listed as threatened under the Endangered Species Act.

The results so far are murky. In a 2008 study, scientists found that trucked coho salmon hadn't spread from the few tributaries where they were released. The situation was complicated by the presence of introduced fish: In 1989, Washington Fish and Wildlife stocked 30,000 non-native rainbow trout in Coldwater Lake to provide angling opportunities within the monument. Since then, some of the trout have spread to nearby tributaries and may have interbred with trucked wild steelhead and wild cutthroat trout. But without detailed molecular studies, scientists can't tell what's going on.

"There can be a variety of unintended consequences in our attempts to help fish recover," says Brian Fransen, a Weyerhaeuser biologist who helped design the 2008 study.

Additional non-native rainbow and brook trout were placed in monument lakes that had been fishless before the eruption. Those fish also colonized monument streams and are undoubtedly changing the local ecology, Crisafulli explains.

Between the fish stocking and sediment dam, "we didn't have the opportunity... to understand what fish were doing naturally," says Fransen. It's now impossible to untangle the human influences from how the mountain might have recovered on its own, and the fish story will never be clear-cut.

 

After stumbling down a hill of bare volcanic rock, Crisafulli enters a cool alder grove. Thin branches form a canopy over a tiny pond; one tree bears the mark of beaver teeth. It's hard to believe that all this was recently rubble. The mountain's recovery is remarkable, but Crisafulli prefers the term "ecological response."

Recovery implies a resetting of the clock back to pre-1980, when in truth, the return of life has been anything but predictable. The eruption wiped some areas clean, while in others, select creatures - pocket gophers, insects, sprouting plant seeds - weathered the blast underground. The result was a patchwork that offered a variety of niches.

"Helens revealed that the chaos was like a lifeboat for organisms," says monument scientist Peter Frenzen. "From the standpoint of a bird, or small mammal, or amphibian, (the jumble) provided places for things to get started."

"A lot of it is like the lottery," Crisafulli says. "What species arrived first, which ones thrive."

Scientists call these stochastic events: unpredictable and with definite effects. And some are driven by humans: The growth of neighboring tree farms, for example, shut out the understory and pushed an excess of elk onto the monument, where the forage is still good and there are no natural predators. Today, signs of their destruction are everywhere: clumps of ripped-up moss, collapsed gopher tunnels, cottonwood trees like twisted bonsai. Mulder has seen stands of Douglas fir "so heavily browsed it looks like someone's been hitting them with a lawnmower."

These far-roaming herbivores also spread seeds with their droppings. At one point, Crisafulli drops to the ground and runs his hands through a clump of ordinary-looking grass. "White clover and an exotic grass from Eurasia," he observes - invasive plants, courtesy of the elk.

Two years ago, the Forest Service launched a pilot program to increase hunting access within the monument. The idea wasn't to kill lots of elk (12 were bagged in the newly opened areas during the 2008-2009 hunting season) but to keep the "very natural elk horde" moving around and overgrazing less, says Mulder. Never mind that it's difficult to know what "natural" means in this case.

 

The monument might have been conceived as a living lab, but boundaries that exist on paper are fluid in the real world, and the ongoing experiment is far from controlled. It is, notes Mulder, "a constant landscape of change," one in the process of reclaiming itself.

Back in 1981, for example, when Corps engineers built the artificial channel out of Coldwater Lake, they lined the sides with steep slopes of riprap. It was meant to force the water on a linear path, yet 30 years later, the stream has eroded, slicing below the riprap into the underlying dirt. To the casual observer today, there is nothing unnatural about the meandering stream flowing between the evenly-placed rock. Everything blends together and the stream flows on, carving its own sinuous path down the mountain.

This story originally appeared in the March 7 issue of High Country News (www.hcn.org).



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