February 28, 2024


A new study makes the case for asteroid strikes setting in motion global glaciation in the distant past
Atmospheric transmission at a wavelength of 500 nm as a function of time after impact. Credit: Science Advances (2024). DOI: 10.1126/sciadv.adk5489

A research team has picked a side in the “Snowball Earth” debate over the possible cause of planet-wide deep freeze events that occurred in the distant past. According to their new study, these so-called “Snowball” Earth periods, in which the planet’s surface was covered in ice for thousands or even millions of years, could have been triggered abruptly by large asteroids that slammed into the Earth.

The findings, detailed in the journal Science Advances, may answer a question that has stumped scientists for decades about some of the most dramatic known climate shifts in Earth’s history. In addition to Yale, the study included researchers from the University of Chicago and the University of Vienna.

Climate modelers have known since the 1960s that if the Earth became sufficiently cold, the high reflectivity of its snow and ice could create a “runaway” feedback loop that would create more sea ice and colder temperatures until the planet was covered in ice. Such conditions occurred at least twice during Earth’s Neoproterozoic era, 720 to 635 million years ago.

Yet efforts to explain what initiated these periods of global glaciation, which have come to be known as “Snowball Earth” events, have been inconclusive. Most theories have centered on the notion that in the atmosphere somehow declined to a point where “snowballing” began.

“We decided to explore an alternative possibility,” said lead author Minmin Fu, the Richard Foster Flint Postdoctoral Fellow in the Department of Earth and Planetary Sciences in Yale’s Faculty of Arts and Sciences. “What if an extraterrestrial impact caused this climate change transition very abruptly?”

For the study, the researchers used a sophisticated climate model that represents atmospheric and , as well as the formation of sea ice, under different conditions. It is the same type of climate model that is used to predict future climate scenarios.

In this instance, the researchers applied their model to the aftermath of a hypothetical asteroid strike in four distinct periods of the past: preindustrial (150 years ago), Last Glacial Maximum (21,000 years ago), Cretaceous (145 to 66 million years ago), and Neoproterozoic (1 billion to 542 million years ago).

For two of the warmer climate scenarios (Cretaceous and preindustrial), the researchers found that it was unlikely that an asteroid strike could trigger global glaciation. But for the Last Glacial Maximum and Neoproterozoic scenarios, when the Earth’s temperature may have been already cold enough to be considered an ice age—an asteroid strike could have tipped Earth into a “Snowball” state.

“What surprised me most in our results is that, given sufficiently cold initial conditions, a ‘Snowball’ state after an asteroid impact can develop over the global ocean in a matter of just one decade,” said co-author Alexey Fedorov, a professor of ocean and atmospheric sciences in Yale’s Faculty of Arts and Sciences. “By then the thickness of sea ice at the Equator would reach about 10 meters. This should be compared to a typical sea ice thickness of one to three meters in the modern Arctic.”

As for the chances of an asteroid-induced “Snowball Earth” period in the years to come, the researchers said it was unlikely—due in part to human-caused warming that has heated the planet—even though other impacts could be as devastating.

Co-authors of the study are Dorian Abbot of the University of Chicago and Christian Koeberl of the University of Vienna.

More information:
Minmin Fu et al, Impact-induced initiation of Snowball Earth: A model study, Science Advances (2024). DOI: 10.1126/sciadv.adk5489. www.science.org/doi/10.1126/sciadv.adk5489

Provided by
Yale University


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A new study makes the case for asteroid strikes setting in motion global glaciation in the distant past (2024, February 9)
retrieved 9 February 2024
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