UNIVERSITY OF SOUTHAMPTON
CREDIT: DR TOM GERNON/UNIVERSITY OF SOUTHAMPTON [@TMGERNON]
Scientists at the University of Southampton have discovered that two intense periods of volcanism triggered a period of global cooling and falling oxygen levels in the oceans, which caused one of the most severe mass extinctions in Earth history.
The researchers, working with colleagues at the University of Oldenburg, the University of Leeds and the University of Plymouth, studied the effects of volcanic ash and lava on ocean chemistry during a period of extreme environmental change around 450 million years ago. Their findings are published in the journal Nature Geoscience.
This period brought about intense planetary cooling, which culminated in a glaciation and the major ‘Late Ordovician Mass Extinction’. This extinction led to the loss of about 85% of species dwelling in the oceans, reshaping the course of evolution of life on Earth.
“It’s been suggested that global cooling was driven by an increase in phosphorus input to the oceans” says Dr Jack Longman, lead author of the study based at the University of Oldenburg, and previously a postdoctoral researcher at Southampton. “Phosphorus is one of the key elements of life, determining the pace at which tiny aquatic organisms like algae can use photosynthesis to convert carbon dioxide (CO2) into organic matter”. These organisms eventually settle to the seabed and are buried, ultimately reducing levels of carbon dioxide in the atmosphere, which then causes cooling.
“The unresolved puzzle is why glaciation and extinction occurred in two distinct phases at this time, separated by about 10 million years”, states Dr Tom Gernon, Associate Professor at the University of Southampton and co-author of the study. “That requires some mechanism to pulse the supply of phosphorus, which is hard to explain”.
The team identified that two exceptionally large pulses of volcanic activity across the globe, occurring in parts of present-day North America and South China, coincided very closely with the two peaks in glaciation and extinction. “But intense bursts of volcanism are more typically linked to massive CO2 release, which should drive global warming, so another process must be responsible for sudden cooling events”, explains Dr Gernon.
This prompted the team to consider whether a secondary process—natural breakdown or ‘weathering’ of the volcanic material—may have provided the surge in phosphorus need to explain the glaciations.
“When volcanic material is deposited in the oceans it undergoes rapid and profound chemical alteration, including release of phosphorus, effectively fertilizing the oceans,” states co-author Professor Martin Palmer from the University of Southampton. “So, it is seemed viable hypothesis and certainly one worth testing”.
“This led our team to study volcanic ash layers in much younger marine sediments to compare their phosphorus contents before and after they were modified by interactions with seawater” said Dr Hayley Manners, a lecturer in Organic Chemistry at the University of Plymouth. Equipped with this information, the team were better placed to understand the potential geochemical impact of extensive volcanic layers from enormous eruptions during the Ordovician.
“This prompted us to develop a global biogeochemical model to understand the knock-on effects on the carbon cycle of rapidly adding a surge of phosphorus leached from volcanic deposits into the ocean”, says Dr Benjamin Mills, Associate Professor at the University of Leeds and co-author on the study.
The team discovered that widespread blankets of volcanic material laid down on the seafloor during the Ordovician Period would have released sufficient phosphorus into the ocean to drive a chain of events, including climatic cooling, glaciation, widespread reduction in ocean oxygen levels, and mass extinction.
Whilst it might be tempting to think that seeding the oceans with phosphorus may help solve the current climate crisis, the scientists caution that this may have more damaging consequences. “Excess nutrient runoff from sources like agricultural fertilisers is a major cause of marine eutrophication – where algae grow rapidly and then decay, consuming oxygen and causing substantial damage to ecosystems at the present day”, cautions Dr Mills.
The scientists conclude that whilst on short timescales massive volcanic eruptions can warm the climate via CO2 emissions, equally they can drive global cooling on multimillion-year timescales. “Our study may prompt reinvestigations of other mass extinctions during Earth history”, concludes Dr Longman.
JOURNAL
Nature Geoscience
DOI
METHOD OF RESEARCH
Computational simulation/modeling
SUBJECT OF RESEARCH
Not applicable
ARTICLE TITLE
Late Ordovician climate change and extinctions driven by elevated volcanic nutrient supply
ARTICLE PUBLICATION DATE
2-Dec-2021
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“But intense bursts of volcanism are more typically linked to massive CO2 release, which should drive global warming…”
Carbon dioxide is a coolant! Its denser nature speeds up conduction as fast as it’s released. Remember thermodynamics? Well, the atmosphere isn’t immune to thermodynamics, you know! Good God!
The role of exhalative volcanics landing in brines (seas) was described by the late Professor R L Stanton in 1987. These volcanics lead to the formation of fine shale deposits at various times throughout geological history. The intriguing aspect of these shales is not only they are responsible for mass extinction events they are also providing the mechanism for distributing large volumes of metals of all classes over vast areas. Later events such as metamorphic activity see the mobilisation of metals from the black shales leading to the accumulations we see today. Famous gold ones include the mid-Ordovician Bendigo Goldfield and the mid Proterozoic Witswatersrand Gold deposits. All of these deposits and many others besides have associated black shales nearby that are all of volcanic affiliation. Later while working in the mid-Devonian shales of the mid west petroleum basins of the USA I found similar geochemical associations with the Bendigo slates and the south Africa equivalents. All of these shales/slates had a high TOC component as well as those from the mid Devonian ‘sedimentary basins. The fossil and bacteria made up most of the TOC. Not a favoured concept by any means – the topic always raises the hackles when brough up.