Size matters, but not exclusively
This is why, in many LIP studies, one of the first questions raised are: how big is this province? The size of the province indicates the amount of magma erupted. By looking at the bubbles of fluids and glass in the volcanic rocks, we will know what gases were released, as well as get an estimate of volatile concentration in the magma. To establish the rate of eruption is quite tricky; it requires high resolution age dating of volcanic rocks from the oldest and the youngest lava flows of the province. However, during the building of a LIP there are many individual eruptions and eruptive events.
It has been shown that although the most magma is erupted in a period of less than 1 million years, the beginning and ending stages may be more prolonged. Even during the main eruptive phase, individual eruptive events are the most significant for determining gas flux. This is especially true since individual eruptions may involve lavas of somewhat different composition, and therefore, different volatile content. If individual flows or flow fields (large areas of lava, from the same magmatic system, erupted within a short period) can be identified and their volume estimated, then one has a way of calculating the probable gas flux for that eruptive event. With this in mind, it is clear that knowing not only the size, but the internal architecture of the province is an essential part of any study aiming to evaluate the environmental effect of a LIP.
In the Kalkarindji LIP one lava unit stands out as an individual eruptive event. The Bingy Bingy member is a porphyry, a fine grained volcanic rock dotted with larger crystals and is thus quite easily distinguished. It crops out over an area of at least 10,000 km2 (about half the size of Wales) and, with an average thickness of c.40m, corresponds to about 400km3 of erupted lava. Using a model developed by the Icelandic researcher Thorardsson and colleagues in 2003, we can estimate that the Bingy Bingy eruption released ca. 2600 megatons of SO2 to the atmosphere. The modern atmosphere contains about three megatonnes SO2 at any one time. No such quick-and-easy model has been developed for CO2, so the CO2 emissions of most LIPs are still much more uncertain.
Type of eruption is also an important factor when it comes to climatic influence. Highly explosive eruptions can inject gas, ash and aerosols into the stratosphere (the atmospheric layer 15 -50 km up, above the troposphere), which maximises their climatic influence. Previously, it had been thought that most, if not all, LIP eruptions were non-explosive. However, recent studies and reviews suggest that explosive eruptions may have played a significant role in some LIP eruptions. What about 510 million years ago?
Explosive magmatism leaves its mark - as brecciated rock, glass shards and sometimes rounded particles called accretionary lapilli. I believe that explosive volcanism may have played an important role in the late stages of the Kalkarindji event. In the East Kimberley and western NT, an extensive volcanic breccia up to 70 m thick could have formed from explosive eruptions. This has previously been interpreted as forming on the top and front of a lava flow as it cooled, solidified, and was fragmented by the flow’s continued movement; but recent work has cast doubt on this hypothesis.
Genetic investigation of a fragmentation process usually involves some assessment of the shapes of the fragments. Quenching, (ie rapid contraction of the hot magma due to contact with surface waters) produces shapes different from those created by explosive gas release and expansion. When particles in the Kalkarindji breccia (the Blackfella Rockhole member) were analysed in this way, researchers concluded that the fragments had probably been formed mainly by magmatic blasts and surges, and by phreatomagmatic processes, (explosions that occur when hot magma interact with water). Only a minority had been formed non-explosively by quenching. This indicates that the Kalkarindji breccia was indeed formed by explosive activity. If this is true, stratospheric disturbance and the related environmental effects would have been prolonged.
Some environmental effects from the Kalkarindji LIP were recorded in the Georgina basin, a sedimentary basin in northern Australia. Researcher Michelle Hough and her colleagues at James Cook University (Townsville, Queensland) studied phosphor-rich sedimentary rocks from the Georgina basin, were deposited in the aftermath of the Kalkarindji eruptions, 510-505 million years ago. They found sulphur with an exceptional isotopic composition - a composition that could only have been due to a global change in ocean chemistry. The studies show that at the time immediately after the Kalkarindji eruptions, the oceans did not contain much oxygen. The easiest explanation for this would be higher temperature: warm waters can hold less oxygen than cold water. A similar shift in the sulphur isotope composition has been noted for other episodes of environmental crisis, for example the end Permian, the most severe of the “big five” mass extinctions. The eruption of the Siberian traps (a truly huge LIP) coincided with this mass extinction.