a bonobo humanity?

Ozone, or trioxygen (O₃₎, an unstable molecule which is regularly produced and destroyed by the action of sunlight on O₂, is a vital feature in our atmosphere. It protects life on earth from the harmful effects of too much UV radiation, which can contribute to skin cancers in humans, and genetic abnormalities in plant life. In a previous post I wrote about the discovery of the ozone shield, and the hole above Antarctica, which we seem to be reducing – a credit to human global co-operation. In this post I’m going to try and get my head around whether or not ozone depletion played a role in the so-called end-Permian extinction of some 250 mya. 

I first read of this theory in David Beerling’s 2009 book The emerald planet, but recent research appears to have backed up Beerling’s scientific speculations – though speculation is too weak a word. Beerling is a world-renowned geobiologist and expert on historical global climate change. He’s also a historian of science, and in ‘An ancient ozone catastrophe?’, chapter 4 of The emerald planet, he describes the discovery and understanding of ozone through the research of Robert Strutt, Christian Schönbein, Marie Alfred Cornu, Walter Hartley, George Dobson, Sidney Chapman and Paul Crutzen, among others. He goes on to describe the ozone hole discovery in the 70s and 80s, before focusing on research into the possible effects of previous events – the Tunguska asteroid strike of 1908, the Mount Pinatubo eruption of 1991 and others – on atmospheric ozone levels, and then homes in on the greatest extinction event in the history of our planet – the end-Permian mass extinction, ‘the Great Dying’, which wiped out some 95% of all species then existing.

According to Beerling, it was an international team of palaeontologists led by Henk Visscher at the University of Utrecht who first made the claim that stratospheric ozone had substantially reduced in the end-Permian. They hypothesised that, due to the greatest volcanic eruptions in Earth history, which created the Siberian Traps (layers of solidified basalt covering a huge area of northern Russia), huge deposits of coal and salt, the largest on Earth, were disrupted:

The widespread heating of these sediments and the action of hot groundwater dissolving the ancient salts, was a subterranean pressure cooker synthesising a class of halogenated compounds called organohalogens, reactive chemicals that can participate in ozone destruction. And in less than half a million years, this chemical reactor is envisaged to have synthesised and churned out sufficiently large amounts of organohalogens to damage the ozone layer worldwide to create an intense increased flux of UV radiation.

However, Beerling questions this hypothesis and considers that it may have been the eruptions themselves, which lasted 2 million years and occurred at the Permian-Triassic boundary 250-252 mya, rather than their impact on salt deposits, that did the damage. There’s evidence that many of the eruptions originated from as deep as 10 kilometres below the surface, injected explosively enough to reach the stratosphere, and that these plumes contained substantial amounts of chlorine. 

More recent research, published this year, has further substantiated Visscher’s team’s finding regarding genetic mutations in ancient conifers and lycopsids, and their probable connection with UV radiation enabled by ozone destruction. The mutations were global and dated to the same period. Laboratory experiments exposing related modern plants to bursts of UV radiation have produced more or less identical spore mutations.

The exact chain of events linking the eruptions to the ozone destruction have yet to be worked out, and naturally there’s a lot of scientific argy-bargy going on, but the whole story, even considering that it occurred so far in the past is a reminder of the fragility of that part of our planet that most concerns us – the biosphere. The eruptions clearly altered atmospheric chemistry and temperature. Isotopic measurements of oxygen in sea water suggest that equatorial waters reached more than 40°C. As can be imagined, this had killer effects on multiple species. 

So, we’re continuing to gain knowledge on the ozone shield and its importance, and fragility. I don’t know that there are too many ozone hole skeptics around (I don’t want to look too hard), but if we could only get the same kind of apparent near-unanimity with regard to anthropogenic global warming, that would be great progress.