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Posted on 10/29/2018 2:21:32 PM PDT by ETL
A new study says we may only have another 1.45 billion years to enjoy the dynamic action of Earth’s geologic engine
There’s no geological artist quite like Earth’s plate tectonics. Thanks to this ongoing operation, we have mountains and oceans, terrifying earthquakes, incandescent volcanic eruptions, and new land being born every single second.
But nothing lasts forever.
Eventually, the mantle will cool to such an extent that this planetwide conveyor belt will grind to a halt. At that point, you can say farewell to the carbon cycle, as well as the constant reshaping and reshuffling of landmasses that have been big drivers of evolution over eons.
Quiming Cheng, a mathematical geoscientist and president of the International Union of Geological Sciences, is the latest to take on the prophetic role of predicting when this bleak day may arrive. He calculates that the shutdown will arrive in about 1.45 billion years. That’s well before the sun is expected to swell into a red giant and consume us in its death throes roughly 5.4 billion years from now. (Here’s why tardigrades may be the only life-forms that survive until the world’s end.)
The study, published this month in Gondwana Research, has provoked controversy, and some experts argue that we can never accurately predict the end of plate tectonics. But scientists largely agree that such an end will arrive one day, putting Earth on a path to a geologic standstill.
So, what will our home world be like when those major planetary processes give up the ghost?
Figuring that out means first understanding how plate tectonics work. Earth was born 4.54 billion years ago in the pyres of the early solar system. Once entirely molten, the heat generated by its formation and radioactive materials in the rock began to escape. As the planet cooled, Earth settled into its current layered structure, with a dense inner iron core, a liquid outer core, and a brittle upper mantle and crust sandwiching the hot, plastic-like rock of the lower mantle.
Anywhere between 600 million and 3.5 billion years ago, slabs made of the crust and upper mantle–collectively known as the lithosphere–became cold and dense enough to be able to sink into the lower mantle, kicking off the era of plate tectonics. The lithosphere became divided into a jigsaw puzzle of plates that are constantly jostling across the planet’s surface, driving geological action above and below the oceans. (Meet the next supercontinent, Pangaea Proxima.)
At mid-ocean ridges, mantle material rises, decompresses, and triggers profuse melting, creating oceanic lithosphere. The colder and denser edges of the slabs help pull this lithospheric plate away from these ridges and down into the depths. They usually dive beneath a less dense oceanic or continental plate in a process known as subduction. This activity generates explosive volcanoes and fresh crust at the surface.
When two continental slabs collide, they buckle, and mountain ranges like the Alps or the Himalaya form. Upwelling mantle plumes can sometimes appear beneath continental or oceanic slabs, and this ever-moving center of melting creates chains of volcanoes.
At some point, though, the mantle will cool to such an extent that the slabs can no longer sink into it, and several studies have attempted to predict when this will transpire.
Cheng’s new paper uses mathematical models to estimate how fast the mantle is cooling, based on what we know about the intensity of the planet’s magmatic activity from three billion years ago to now. That, he says, gives us a first-order estimate of when plate tectonics will end.
Regardless of the precision of this figure, plate tectonics will inevitably perish, says Ken Hudnut, a research geophysicist working with the United States Geological Survey. When that day arrives, it “may well be the end of the world as we know it.”
Earth would likely enter a single lid regime, a completed jigsaw of titanic slabs that will no longer drift or sink. Mountain building will stop, but Earth will still have an atmosphere, so erosion by wind and waves will shave down the mighty peaks to hilly plateaus. Eventually, much of the flattened continents will be underwater.
Subduction zones will no longer exist, so while earthquakes will still happen every now and then, truly earthshattering events above magnitude 7 or so will be consigned to history. At the same time, much of the world’s explosive volcanism would be extinguished—although volcanoes would not be entirely snuffed out.
Mars, a world of failed plate tectonics, did manage to forge some impressive volcanic features, including Olympus Mons, the largest volcano in the solar system. Without moving plates, a long-lived upwelling mantle plume focused plenty of crustal melting on that one single spot.
While the mantle of future Earth remains warm enough to convect and partially melt, we would get similar but scattered stationary hot spots of plume-driven volcanism. We would never get anything as large as Olympus Mons on Earth, as our gravitational field is too strong, and anything that massive and tall would simply sink into the crust. Instead, our voluminous volcanoes would be flatter and far more spread out.
And as happens today, parts of the lower lithosphere would continue to peel off and fall into particularly hot parts of the mantle. This would cause mantle material to rise in its place, pushing up the crust and forming isolated mountain ranges and associated basins. This activity would cause minor earthquakes and maybe even additional pockets of volcanism.
“These are the processes that shape Venus' surface,” says Robert Stern, a plate tectonics expert at the University of Texas at Dallas, referring to another world without fully-functioning plate tectonics. But eventually, as cooling continues, those mechanisms will also cease to be, and the planet’s final volcanic lights will be snuffed out. The mantle will be relatively frigid, and Earth will “become a dead planet, like Mercury,” he says.
Perhaps just before it does, Earth’s liquid core will cool enough to end convection, causing the planet’s protective magnetic field to fail. The sun’s stream of energetic particles will strip away our atmosphere, and its expansion will boil away the oceans.
“There is not a lot to look forward to after plate tectonics’ demise,” Hudnut says. The planet will just keep getting flatter and more boring, he predicts, until “Earth splashes into what’s left of the sun.”
Other researchers have come up with different plate tectonic death dates. One 2016 study used extremely detailed but simplified computer simulations to put the end date at five billion years, roughly around the time of the sun’s demise.
Another 2008 paper used evidence of past plate tectonic activity to suggest that plate tectonics are intermittent. Its authors predict that the next major pause will take place 350 million years from now, when the Pacific Ocean closes and its many subduction zones deactivate.
I will bet 400 quintrillion dollars ($4.00 in today’s money) they are wrong.
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ind, a stream of charged particles emanating from the Sun. Its magnitude at the Earth’s surface ranges from 25 to 65 microteslas (0.25 to 0.65 gauss).[3]
Approximately, it is the field of a magnetic dipole currently tilted at an angle of about 11 degrees with respect to Earth’s rotational axis, as if there were a bar magnet placed at that angle at the center of the Earth.
The North geomagnetic pole, located near Greenland in the northern hemisphere, is actually the south pole of the Earth’s magnetic field, and the South geomagnetic pole is the north pole.
The magnetic field is generated by electric currents due to the motion of convection currents of molten iron in the Earth’s outer core driven by heat escaping from the core, a natural process called a geodynamo.
While the North and South magnetic poles are usually located near the geographic poles, they can wander widely over geological time scales, but sufficiently slowly for ordinary compasses to remain useful for navigation.
However, at irregular intervals averaging several hundred thousand years, the Earth’s field reverses and the North and South Magnetic Poles relatively abruptly switch places.
These reversals of the geomagnetic poles leave a record in rocks that are of value to paleomagnetists in calculating geomagnetic fields in the past. Such information in turn is helpful in studying the motions of continents and ocean floors in the process of plate tectonics.
The magnetosphere is the region above the ionosphere that is defined by the extent of the Earth’s magnetic field in space. It extends several tens of thousands of kilometers into space, protecting the Earth from the charged particles of the solar wind and cosmic rays that would otherwise strip away the upper atmosphere, including the ozone layer that protects the Earth from harmful ultraviolet radiation.
We’re all gonna die ping.
From the article...
“Perhaps just before it does, Earth’s liquid core will cool enough to end convection, causing the planet’s protective magnetic field to fail. The sun’s stream of energetic particles will strip away our atmosphere, and its expansion will boil away the oceans.”
“Scientists will harness the awesome power of cow farts, the phenomena that led to global warming and extinction of all humans by drowning the world 1.4 billion years ago, to remelt the Earth’s core.”
We'll all be long dead before the earth runs out of radioactive elements to maintain a molten core.
Should I pull my money out of my 401k?
I think as long as the Earth spins on its axis and the moon orbits the Earth we will have plate tectonics.
The Earth spinning, and the moon orbiting deform the Earth’s mantle causing a tidal bulge, creating heat and movement.
Until the moon escapes Earth orbit or its orbit is so far from Earth that it no longer deforms the mantle we will have plate movement.
Another thing is we’ll no longer have heavy elements near the surface, which our bodies need (even trace amounts of gold is needed). We have access to these heavy elements because earthquakes, tsunamis and hurricanes stir them up from the bottom of the oceans and lower layers of the earth’s crust up to where tiny portions of them get consumed.
Yet another big ol’ honkin’ example of fine tuning by a Creator so advanced life can exist on Earth. If the long cycle for plate tectonics didn’t happen to be timed to have nice activity when other things in the Earth were timed right (i.e. stable orbit around the sun, stable rotation, stable burning phase of our sun) then advanced life wouldn’t have had a chance to exist at any point on earth.
And the atheist libs say the Christians are “anti-science”.
Lucky for me...I’ll be dead!!!!
All very interesting, but I’d say, if more than $1. of our tax money is going to these dreamers, cut the funding today.
There is no reason to study it further, and I doubt we’ll ever recover any benefit, or “bang for our buck”.
(Here’s why tardigrades may be the only life-forms that survive until the world’s end.)
...
For those who don’t know, Keith Richards is a tardigrade.
“...Carbon cycle...”. I thought all the petroleum came from dinosaurs.
Thanks colorado tanker. My guess is, another kludge will be invented. :^)
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Well . . . yeah. That’s what makes it funny.
Women and children hurt biggly.
Oddly, they have no idea how the plates started to move in the first place.
... at the same time my property taxes are lost somewhere in the Los Angeles postal system!!!! Irritating!
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