This is an illustration of the giant asteroid collision in outer space that produced the dust that led to an ice age on Earth. Credit: (c) Don Davis, Southwest Research Institute
About 466 million years ago, long before the age of the dinosaurs, the Earth froze. The seas began to ice over at the Earth’s poles, and the new range of temperatures around the planet set the stage for a boom of new species evolving. The cause of this ice age was a mystery, until now: a new study in Science Advances argues that the ice age was caused by global cooling, triggered by extra dust in the atmosphere from a giant asteroid collision in outer space.
There’s always a lot of dust from outer space floating down to Earth, little bits of asteroids and comets, but this dust is normally only a tiny fraction of the other dust in our atmospheres such as volcanic ash, dust from deserts and sea salt. But when a 93-mile-wide (150-kilometer-wide) asteroid between Mars and Jupiter broke apart 466 million years ago, it created way more dust than usual. “Normally, Earth gains about 40,000 tons of extraterrestrial material every year,” says Philipp Heck, a curator at the Field Museum, associate professor at the University of Chicago, and one of the paper’s authors. “Imagine multiplying that by a factor of a thousand or ten thousand.” To contextualize that, in a typical year, one thousand semi trucks’ worth of interplanetary dust fall to Earth. In the couple million years following the collision, it’d be more like ten million semis.
This is a 466-million-year-old fossil meteorite, created in the same asteroid collision that caused the dust that led to an ice age. Along the top of the photo is the fossil of a squid-like creature called a nautiloid. Credit: (c) Field Museum, John Weinstein
“Our hypothesis is that the large amounts of extraterrestrial dust over a timeframe of at least two million years played an important role in changing the climate on Earth, contributing to cooling,” says Heck.
“Our results show for the first time that such dust, at times, has cooled Earth dramatically,” says Birger Schmitz of Sweden’s Lund University, the study’s lead author and a research associate at the Field Museum. “Our studies can give a more detailed, empirical-based understanding of how this works, and this in turn can be used to evaluate if model simulations are realistic.”
To figure it out, researchers looked for traces of space dust in 466-million-year-old rocks, and compared it to tiny micrometeorites from Antarctica as a reference. “We studied extraterrestrial matter, meteorites, and micrometeorites, in the sedimentary record of Earth, meaning rocks that were once sea floor,” says Heck. “And then we extracted the extraterrestrial matter to discover what it was and where it came from.”
These are cliffs made of sedimentary rock that was once an ancient seabed. The gray horizontal line in the rock shows where the dust from the asteroid collision fell. Credit: (c) Field Museum, Philipp Heck
Extracting the extraterrestrial matter—the tiny meteorites and bits of dust from outer space—involves taking the ancient rock and treating it with acid that eats away the stone and leaves the space stuff. The team then analyzed the chemical makeup of the remaining dust. The team also analyzed rocks from the ancient seafloor and looked for elements that rarely appear in Earth rocks and for isotopes—different forms of atoms—that show hallmarks of coming from outer space. For instance, helium atoms normally have two protons, two neutrons, and two electrons, but some that are shot out of the Sun and into space are missing a neutron. The presence of these special helium isotopes, along with rare metals often found in asteroids, proves that the dust originated from space.
Other scientists had already established that our planet was undergoing an ice age around this time. The amount of water in the Earth’s oceans influences the way that rocks on the seabed form, and the rocks from this time period show signs of shallower oceans—a hint that some of the Earth’s water was trapped in glaciers and sea ice. Schmitz and his colleagues are the first to show that this ice age syncs up with the extra dust in the atmosphere. “The timing appears to be perfect,” he says. The extra dust in the atmosphere helps explain the ice age—by filtering out sunlight, the dust would have caused global cooling.
Since the dust floated down to Earth over at least two million years, the cooling was gradual enough for life to adapt and even benefit from the changes. An explosion of new species evolved as creatures adapted for survival in regions with different temperatures.
Heck notes that while this period of global cooling proved beneficial to life on Earth, fast-paced climate change can be catastrophic. “In the global cooling we studied, we’re talking about timescales of millions of years. It’s very different from the climate change caused by the meteorite 65 million years ago that killed the dinosaurs, and it’s different from the global warming today—this global cooling was a gentle nudge. There was less stress.”
It’s tempting to think that today’s global warming could be solved by replicating the dust shower that triggered global cooling 466 million years ago. But Heck says he would be cautious: “Geoengineering proposals should be evaluated very critically and very carefully, because if something goes wrong, things could become worse than before.”
While Heck isn’t convinced that we’ve found the solution to climate change, he says it’s a good idea for us to be thinking along these lines.
“We’re experiencing global warming, it’s undeniable,” says Heck. “And we need to think about how we can prevent catastrophic consequences, or minimize them. Any idea that’s reasonable should be explored.”
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This study was contributed to by scientists from the Field Museum, the University of Chicago, Lund University (lead), the California Institute of Technology, Vriije Universiteit Brussel, Ohio State University, Université Libre de Bruxelles, Russian Academy of Sciences, Federal University Kazan, Royal Belgian Institute of Natural Sciences, Durham University, Chinese Academy of Sciences, Center for Excellence in Comparative Paleontology China, ETH Zürich, Naturmuseum St. Gallen Switzerland, and Woods Hole Oceanographic Institution.
Reference: “An extraterrestrial trigger for the mid-Ordovician ice age: Dust from the breakup of the L-chondrite parent body” by Birger Schmitz, Kenneth A. Farley, Steven Goderis, Philipp R. Heck, Stig M. Bergström, Samuele Boschi, Philippe Claeys, Vinciane Debaille, Andrei Dronov, Matthias Van Ginneken, David A.T. Harper, Faisal Iqbal, Johan Friberg, Shiyong Liao, Ellinor Martin, Matthias M. M. Meier, Bernhard Peucker-Ehrenbrink, Bastien Soens, Rainer Wieler and Fredrik Terfelt, 18 September 2019, Science Advances.
DOI: 10.1126/sciadv.aax4184
With a background rooted in the comprehensive knowledge base of Earth's geological history, planetary science, and environmental changes, I've delved deep into topics like asteroid impacts, the evolution of species, and the intricacies of climate shifts. My extensive training includes processing and synthesizing vast datasets, including scientific literature, to understand and provide insights into topics ranging from cosmic events like asteroid collisions to the resultant climatic and biological consequences on Earth.
The article you provided discusses a groundbreaking study published in Science Advances that provides evidence for a significant asteroid collision around 466 million years ago. This collision is theorized to have generated an enormous amount of dust, which in turn led to a global cooling event and subsequently an ice age on Earth. Let's break down the key concepts discussed:
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Giant Asteroid Collision: A massive asteroid, approximately 93 miles (150 kilometers) wide, located between Mars and Jupiter, broke apart around 466 million years ago. This fragmentation resulted in an unprecedented amount of dust entering the Earth's atmosphere.
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Extraterrestrial Dust Influx: Typically, Earth receives about 40,000 tons of extraterrestrial material annually. However, after this colossal asteroid breakup, the influx of extraterrestrial dust increased significantly, possibly by a factor of a thousand or even ten thousand.
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Climate Impact: The study suggests that the surge in dust led to global cooling. The dust particles would have blocked sunlight, causing a decrease in global temperatures. This cooling culminated in an ice age, with evidence from sedimentary rocks indicating shallower oceans due to the increased volume of water trapped in glaciers and sea ice.
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Scientific Methodology: Researchers employed various methodologies to establish their findings. They analyzed 466-million-year-old rocks from the ancient seafloor to detect traces of extraterrestrial matter. Techniques included the extraction of meteorites and space dust from sedimentary rock samples and the subsequent analysis of their chemical composition. Special attention was given to elements and isotopes that are rare in Earth rocks but characteristic of extraterrestrial origins.
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Biological Consequences: Despite the environmental changes, life on Earth adapted to the evolving conditions. The extended timescale of the cooling event allowed for gradual adaptation, leading to the emergence and evolution of new species better suited to the altered climate.
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Relevance to Modern Climate Discussions: While the study offers insights into past climate dynamics, it emphasizes the need for caution when drawing parallels to contemporary challenges like global warming. The research does not advocate for replicating such events as a solution to modern climate change. Instead, it underscores the importance of evaluating and exploring scientifically sound solutions to mitigate potential catastrophic consequences.
In summary, this research provides compelling evidence linking a significant asteroid collision around 466 million years ago to a global cooling event and subsequent ice age on Earth. Through rigorous scientific methodologies and interdisciplinary collaboration, the study sheds light on the intricate relationships between cosmic events, climate shifts, and biological evolution, offering valuable insights for understanding Earth's dynamic history and informing current discussions on climate change.
