November 23, 2024

Uncovering “Snowball Earth”: Hidden Rock Record Unveils Secrets of Earth’s Deep Freeze

Snowball EarthSnowball Earth
A study by UCL researchers identifies the Port Askaig Formation in Ireland and Scotland as potentially the most complete geological record of the “snowball Earth” phenomenon, marking a period when the entire planet was encased in ice. This formation, unique for its clear transition from a tropical environment, provides crucial insights into the conditions that may have spurred the development of complex, multicellular life following the planet’s thaw. Artists impression of ‘Snowball Earth’. Credit: NASA

Research on the Port Askaig Formation in Ireland and Scotland suggests it is a key geological record of Earth’s ice-covered era, providing unique geological insights into the prelude to complex life evolution.

A team of researchers led by the University College London (UCL) has discovered that a rock formation in Ireland and Scotland may represent the most extensive record of the “snowball Earth” event, a critical phase in Earth’s history when the entire planet was encased in ice.

The research, published in the Journal of the Geological Society of London, reveals that the Port Askaig Formation, composed of layers of rock up to 1.1km thick, was likely laid down between 662 to 720 million years ago during the Sturtian glaciation – the first of two global freezes thought to have triggered the development of complex, multicellular life.

'The Bubble' on Eileach an Naoimh'The Bubble' on Eileach an Naoimh
An outcrop called ‘the Bubble’ on Eileach an Naoimh (Holy Isle). It shows a huge white rock fragment, tens of metres across, which was originally part of the underlying rock sequence. The layering in the carbonate rock has been squeezed tightly under immense pressure and transported by thick ice sheets to its final resting as one of many different rock fragments within a moraine. Credit: Graham Shields

Unique Geological Insights

One exposed outcrop of the formation, found on Scottish islands called the Garvellachs, is unique as it shows the transition into “snowball Earth” from a previously warm, tropical environment. Other rocks that formed at a similar time, for instance in North America and Namibia, are missing this transition.

“These rocks record a time when Earth was covered in ice. All complex, multicellular life, such as animals, arose out of this deep freeze, with the first evidence in the fossil record appearing shortly after the planet thawed,” said senior author Professor Graham Shields, of UCL Earth Sciences.

First author Elias Rugen, a PhD candidate at UCL Earth Sciences, said: “Our study provides the first conclusive age constraints for these Scottish and Irish rocks, confirming their global significance.

Anthony SpencerAnthony Spencer
Anthony (Tony) Spencer, co-author of the latest study and of a classic 1971 memoir about the rocks, standing in 2023 on glacial till (sediment deposited by a glacier) of the Port Askaig Formation on Garbh Eileach, the largest of the Garvellach islands. Credit: Graham Shield

“The layers of rock exposed on the Garvellachs are globally unique. Underneath the rocks laid down during the unimaginable cold of the Sturtian glaciation are 70 metres of older carbonate rocks formed in tropical waters. These layers record a tropical marine environment with flourishing cyanobacterial life that gradually became cooler, marking the end of a billion years or so of a temperate climate on Earth.

“Most areas of the world are missing this remarkable transition because the ancient glaciers scraped and eroded away the rocks underneath, but in Scotland by some miracle the transition can be seen.”

Anthony Spencer on Garbh Eileach FormationAnthony Spencer on Garbh Eileach Formation
Co-author Anthony (Tony) Spencer standing on the Garbh Eileach Formation. The rocks record a gradual transition from the warm tropical world of the Tonian period into the snowball Earth of the Cryogenian period. Credit: Elias Rugen

Theoretical and Historical Context

The Sturtian glaciation lasted approximately 60 million years and was one of two big freezes that occurred during the Cryogenian Period (between 635 and 720 million years ago). For billions of years prior to this period, life consisted only of single-celled organisms and algae.

After this period, complex life emerged rapidly, in geologic terms, with most animals today similar in fundamental ways to the types of life forms that evolved more than 500 million years ago. One theory is that the hostile nature of the extreme cold may have prompted the emergence of altruism, with single-celled organisms learning to cooperate with each other, forming multicellular life.

Limestone Beds of the Garvellach FormationLimestone Beds of the Garvellach Formation
Standing on limestone beds of the pre-glacial Garvellach Formation, looking North from Garbh Eileach over to Dun Chonnuil. Due to tectonic tilting, the sedimentary layers get younger, and closer to the onset of glaciation, as you move to the right. Credit: Elias Rugen

The advance and retreat of the ice across the planet was thought to have happened relatively quickly, over thousands of years, because of the albedo effect – that is, the more ice there is, the more sunlight is reflected back into space, and vice versa.

Professor Shields explained: “The retreat of the ice would have been catastrophic. Life had been used to tens of millions of years of deep freeze. As soon as the world warmed up, all of life would have had to compete in an arms race to adapt. Whatever survived were the ancestors of all animals.”

Research Methodology and Findings

For the new study, the research team collected samples of sandstone from the 1.1km-thick Port Askaig Formation as well as from the older, 70-metre-thick Garbh Eileach Formation underneath.

View of Garbh EileachView of Garbh Eileach
A view of Garbh Eileach, the largest island in the Garvellach island chain where the gradational transition into snowball Earth is recorded. Credit: Graham Shields

They analyzed tiny, extremely durable minerals in the rock called zircons. These can be precisely dated as they contain the radioactive element uranium, which converts (decays) to lead at a steady rate. The zircons together with other geochemical evidence suggest the rocks were deposited between 662 and 720 million years ago.

Potential Global Significance

The researchers said the new age constraints for the rocks may provide the evidence needed for the site to be declared as a marker for the start of the Cryogenian Period.

This marker, known as a Global Boundary Stratotype Section and Point (GSSP), is sometimes referred to as a golden spike, as a gold spike is driven into the rock to mark the boundary. GSSPs attract visitors from around the world and in some cases museums have been established at the sites.

A group from the International Commission on Stratigraphy, a part of the International Union of Geological Sciences, visited the Garvellachs in July to assess the case for a golden spike on the archipelago. Currently, the islands are only accessible by chartering a boat or by sailing or kayaking to them.

The study involved researchers from UCL, the University of Milano-Bicocca, Italy, and Birkbeck University of London. The work was funded by the Natural Environment Research Council (NERC).

Reference: “Glacially influenced provenance and Sturtian affinity revealed by detrital zircon U–Pb ages from sandstones in the Port Askaig Formation, Dalradian Supergroup” by Elias J. Rugen, Guido Pastore, Pieter Vermeesch, Anthony M. Spencer, David Webster, Adam G. G. Smith, Andrew Carter, and Graham A. Shields, 16 August 2024, Journal of the Geological Society.
DOI: 10.1144/jgs2024-029