Posted on 09/02/2014 7:32:13 PM PDT by null and void
An aerial flight over Yellowstones Midway Geyser Basin in 2004 shows Grand Prismatic Spring and Excelsior Geyser Crater, which drain into the nearby Firehole River. Courtesy of USGS
In the unlikely event of a volcanic supereruption at Yellowstone National Park, the northern Rocky Mountains would be blanketed in meters of ash, and millimeters would be deposited as far away as New York City, Los Angeles and Miami, according to a new study.
An improved computer model developed by the studys authors finds that the hypothetical, large eruption would create a distinctive kind of ash cloud known as an umbrella, which expands evenly in all directions, sending ash across North America.
A supereruption is the largest class of volcanic eruption, during which more than 1,000 cubic kilometers (240 cubic miles) of material is ejected. If such a supereruption were to occur, which is extremely unlikely, it could shut down electronic communications and air travel throughout the continent, and alter the climate, the study notes.
A giant underground reservoir of hot and partly molten rock feeds the volcano at Yellowstone National Park. It has produced three huge eruptions about 2.1 million, 1.3 million and 640,000 years ago. Geological activity at Yellowstone shows no signs that volcanic eruptions, large or small, will occur in the near future. The most recent volcanic activity at Yellowstone a relatively non-explosive lava flow at the Pitchstone Plateau in the southern section of the park occurred 70,000 years ago.
Researchers at the U.S. Geological Survey used a hypothetical Yellowstone supereruption as a case study to run their new model that calculates ash distribution for eruptions of all sizes. The model, Ash3D, incorporates data on historical wind patterns to calculate the thickness of ash fall for a supereruption like the one that occurred at Yellowstone 640,000 years ago.
The new study provides the first quantitative estimates of the thickness and distribution of ash in cities around the U.S. if the Yellowstone volcanic system were to experience this type of huge, yet unlikely, eruption.
Cities close to the modeled Yellowstone supereruption could be covered by more than a meter (a few feet) of ash. There would be centimeters (a few inches) of ash in the Midwest, while cities on both coasts would see millimeters (a fraction of an inch) of accumulation, according to the new study that was published online today in Geochemistry, Geophysics, Geosystems, a journal of the American Geophysical Union. The paper has been made available at no charge at http://onlinelibrary.wiley.com/doi/10.1002/2014GC005469/abstract.
The model results help scientists understand the extremely widespread distribution of ash deposits from previous large eruptions at Yellowstone. Other USGS scientists are using the Ash3D model to forecast possible ash hazards at currently restless volcanoes in Alaska.
Unlike smaller eruptions, whose ash deposition looks roughly like a fan when viewed from above, the spreading umbrella cloud from a supereruption deposits ash in a pattern more like a bulls eye heavy in the center and diminishing in all directions and is less affected by prevailing winds, according to the new model.
In essence, the eruption makes its own winds that can overcome the prevailing westerlies, which normally dominate weather patterns in the United States, said Larry Mastin, a geologist at the USGS Cascades Volcano Observatory in Vancouver, Washington, and the lead author of the new paper. Westerly winds blow from the west.
This helps explain the distribution from large Yellowstone eruptions of the past, where considerable amounts of ash reached the west coast, he added.
The three large past eruptions at Yellowstone sent ash over many tens of thousands of square kilometers (thousands of square miles). Ash deposits from these eruptions have been found throughout the central and western United States and Canada.
Erosion has made it difficult for scientists to accurately estimate ash distribution from these deposits. Previous computer models also lacked the ability to accurately determine how the ash would be transported.
Using their new model, the studys authors found that during very large volcanic eruptions, the expansion rate of the ash clouds leading edge can exceed the average ambient wind speed for hours or days depending on the length of the eruption. This outward expansion is capable of driving ash more than 1,500 kilometers (932 miles) upwind westward and crosswind north to south producing a bulls eye-like pattern centered on the eruption site.
In the simulated modern-day eruption scenario, cities within 500 kilometers (311 miles) of Yellowstone like Billings, Montana, and Casper, Wyoming, would be covered by centimeters (inches) to more than a meter (more than three feet) of ash. Upper Midwestern cities, like Minneapolis, Minnesota, and Des Moines, Iowa, would receive centimeters (inches), and those on the East and Gulf coasts, like New York and Washington, D.C. would receive millimeters or less (fractions of an inch). California cities would receive millimeters to centimeters (less than an inch to less than two inches) of ash while Pacific Northwest cities like Portland, Oregon, and Seattle, Washington, would receive up to a few centimeters (more than an inch).
Even small accumulations only millimeters or centimeters (less than an inch to an inch) thick could cause major effects around the country, including reduced traction on roads, shorted-out electrical transformers and respiratory problems, according to previous research cited in the new study. Prior research has also found that multiple inches of ash can damage buildings, block sewer and water lines, and disrupt livestock and crop production, the study notes.
The study also found that other eruptions powerful but much smaller than a Yellowstone supereruption might also generate an umbrella cloud.
These model developments have greatly enhanced our ability to anticipate possible effects from both large and small eruptions, wherever they occur, said Jacob Lowenstern, USGS Scientist-in-Charge of the Yellowstone Volcano Observatory in Menlo Park, California, and a co-author on the new paper.
i have a question,isn’t 40/50% of volcanic ash cocaine? maybe we can sell it to south america?
Can’t get enough of these “unlikely alerts.”
Extremely unlikely? It’s all but inevitable. And based on the geologic record showing it’s happened with fair regularity about every 600 thousand years it’s just about due. Maybe in another hundred thousand years or maybe next month. And there’s not a damned thing anyone can do about it. It’s sort of like, well, death. Worrying about it is a horrible waste of the limited time we have to enjoy the wonders set before us. But unlike anthropomorphic global warming, second hand cigarette smoke, and CFC ozone depletion Yellowstone isn’t a myth or hoax, and when it goes off it really will change humanity and all other life on this planet. No one was taking notes last time but the earth tells the story.
Maybe I’m wrong, but I have seen articles that claim that the ash from the eruption 640,000 years ago were 300 feet thick as far away as what is now Illinois. Also, that cities “close” to the eruption, some 300 miles, would be obliterated by the blast, then buried. Their contention that the “unlikely” (repeated as a mantra throughout the article) eruption would deposit ash only 3 feet thick close to the eruption site seems at odds with what I have read before (putting it politely). After all, 1000 cubic miles of ash is a LOT (10 miles per side cube).
Have you ever shoveled “ash?” It’s REALLY heavy!
Volnado?
“And based on the geologic record showing its happened with fair regularity about every 600 thousand years its just about due.” “...but the earth tells the story.”
Now you’ve done it. Unless they are super involved in a discussion on the Religion Thread.
“shovels and trash bags, ash problem solved.
At my house anyways”
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There will be plenty of warning if we’re unlucky enough to live in the time of the next eruption. Warning for evacuation (where that is prudent) and warning for preparation where necessary. If the warning signs of a impending happen, you’d also want to stock up on those things that will be in temporary short supply (e.g., multiple engine air filters and cabin filters for the model{s} of car{s}/truck{s} you and your family own) since those shortages will last for a while.
Like you, I've also read that the cover would be much thicker much farther out.
If someone is really worried about this, they should try and get a job very close to Yellowstone.
If it is as bad as some scientists claim, then it would be better to be obliterated in the initial explosion than try to eke out an existence on an earth doomed to years of massive crop failures, starvation, and dropping temperatures.
Would a snowblower work?
It might take a while to shovel then. lol
I really doubt it is cocaine
On the other hand, if you survive—no stamps, screw the limits and fish year ‘round.
Ash Alert indeed.
Ash3d: Now With More Boomstick.
Climate change, algore predictions are always true doncha know?
Many volcanic areas are “restless.” As the magnetic north pole has moved beyond axis north and continues ever more quicky toward Russia, the outer iron core moves faster. When it gets to near 25 degrees above the equator, it might move about 50 degrees within about a year. In the near future, the central Rockies here may be interesting indeed.
Inevitable indeed. From what they’ve been able to discern, the eruptions occur when the magma finds a weak spot in the crust. The caldera appears to ‘move’ since the plate has crept along over millions of years. Literally a matter of time until it finds another release point.
Shop smart. Shop S-mart!
To clarify...the asteroid impacts on Yellowstone.
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