Astrophysics and Extinctions:
News About Planet-Threatening Events
The Geological Society of
America October 7, 2011-Space is a violent place. If a star explodes or
black holes collide anywhere in our part of the Milky Way, they’d give off
colossal blasts of lethal gamma-rays, X-rays and cosmic rays and it’s
perfectly reasonable to expect Earth to be bathed in them. A new study of such
events has yielded some new information about the potential effects of what are
called “short-hard” interstellar radiation events.
Several studies in the past have
demonstrated how longer high-energy radiation bursts, such as those caused by
supernovae, and extreme solar flares can deplete stratospheric ozone, allowing
the most powerful and damaging forms of ultraviolet radiation to penetrate to
the Earth’s surface. The probability of an event intense enough to disrupt
life on the land or in the oceans becomes large, if considered on geological
timescales. So getting a handle on the rates and intensities of such events is
important for efforts to connect them to extinctions in the fossil record.
“We find that a kind of gamma
ray burst — a short gamma ray burst — is probably more significant than a
longer gamma ray burst,” said astrophysicist Brian Thomas of Washburn
University. Improved and accumulated data collected by the SWIFT satellite,
which catches gamma ray bursts in action in other galaxies, is providing a
better case for the power and threat of the short bursts to life on Earth.
The shorter bursts are really
short: less than one second long. They are thought to be caused by the collision
of two neutron stars or maybe even colliding black holes. No one is certain
which. What is clear is that they are incredibly powerful events.
“The duration is not as
important as the amount of radiation,” said Thomas. If such a burst were to
happen inside the Milky Way, it its effects would be much longer lasting to
Earth’s surface and oceans.
“What I focused on was the
longer term effects,” said Thomas. The first effect is to deplete the ozone
layer by knocking free oxygen and nitrogen atoms so they can recombine into
ozone-destroying nitrous oxides. These long-lived molecules keep destroying
ozone until they rain out. “So we see a big impact on the ozone layer.”
Those effects are likely to have
been devastating for many forms of life on the surface -- including terrestrial
and marine plants which are the foundation of the food web.
Based on what is seen among other
galaxies, these short bursts, it seems that they occur in any given galaxy at a
rate of about once per 100 million years. If that is correct, then it’s very
likely that Earth has been exposed to such events scores of times over its
history. The question is whether they left a calling card in the sky or
Earth’s geological record.
Astronomical evidence is not
likely, said Thomas, because the galaxy spins and mixes pretty thoroughly every
million years, so any remnants of blasts are probably long gone from view. There
might, however, be evidence in the ground here on Earth, he said. Some
researchers are looking at the isotope iron-60, for instance, which has been
argued as a possible proxy for radiation events.
If isotopes like iron-60 can
reveal the strata of the events, it then becomes a matter of looking for
extinction events that correlate and seeing what died and what survived -- which
could shed more light on the event itself.
“I work with some
paleontologists and we try to look for correlations with extinctions, but they
are skeptical,” said Thomas. “So if you go and give a talk to
paleontologists, they are not quite into it. But to astrophysicists, it seems
pretty plausible.”
Thomas will be presenting his
work on Sunday morning October 9, 2011, at the annual meeting of the Geological
Society of America in Minneapolis. This work was supported by the NASA
Astrobiology: Exobiology and Evolutionary Biology Program.
Credit:Brian C. Thomas Washburn
University
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