A New Explanation For Snowball Earth

A new study by Earth scientists in the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) offers an explanation for one of Earth’s great climate puzzles: how the Sturtian glaciation, an ancient ice age when the planet was nearly entirely frozen, could have lasted 56 million years – far longer than standard climate models have predicted. This lengthy freeze took place during Earth’s Cryogenian period, roughly 717 to 660 million years ago, predating dinosaurs and complex plant life.

The research is published in Proceedings of the National Academy of Sciences and led by graduate student Charlotte Minsky, who is advised by co-author Robin Wordsworth, the Gordon McKay Professor of Environmental Science and Engineering and Professor of Earth and Planetary Sciences. Co-authors are David T. Johnston and Andrew H. Knoll.

Using a coupled model of the ancient climate and the global carbon cycle, the researchers make the case that Earth may not have been locked in a single, unbroken “Snowball Earth” state, or period when the entire planet was frozen. Instead, they find that the planet likely oscillated between fully ice-covered “snowball” conditions and ice-free “hothouse” intervals throughout the Sturtian period.

Sturtian stratigraphic successions including evidence of intermittent open water: syn-glacial carbonate deposition sites (1) and ice-rafted debris margin sites (2). Site locations and paleocontinent configurations adapted from Hoffman (3) and Li et al. (4). Paleocontinents at 720 Ma: Amaz – Amazonia; Av – Avalonia; Balt – Baltica; Congo; EAnt – East Antarctica; ESv – East Svalbard; G – Greenland; Ind – India; K – Kalahari; Laur – Laurentia; NA – North Australia; NCh – North China; R – Rio de la Plata; S – Sahara; SA – South Australia; SCh – South China; SF – São Francisco; Sib – Siberia; Tm – Tarim; WAfr – West Africa.— Proceedings of the National Academy of Sciences

The team’s simulations suggest that intense weathering of basalt in the Franklin Large Igneous Province, a vast volcanic region located in northern Canada and believed to have erupted just before the onset of the Sturtian glaciation, drew down atmospheric carbon dioxide enough to trigger multiple global glaciations.

As volcanoes and other processes slowly rebuilt atmospheric carbon dioxide, the climate warmed, the ice retreated, and large areas of fresh basalt were again exposed to the atmosphere. Renewed breakdown from weathering then pulled carbon dioxide back down, pushing the climate into another Snowball phase. This repeating cycle of carbon dioxide-driven freezing and thawing, the authors argue, could naturally sustain glacial–interglacial swings over tens of millions of years.

The mechanisms revealed by the Harvard study resolve several longstanding paradoxes, most notably the previously inexplicable length of the Sturtian when compared with physical climate models. The study also matches observed sedimentary patterns from that time period and explains how atmospheric oxygen levels could have remained stable despite extreme climate upheavals.

Repeated returns to warmer, ice-free conditions may have helped prevent a complete collapse of atmospheric oxygen, the study further suggests. “This could help explain how aerobic life persisted through such an extreme interval,” Minsky said.

Schematic of key carbon, oxygen, and weathering processes during interglacial and Snowball states. During interglacials, silicate weathering – including an enhanced basalt weathering flux from the LIP – draws down CO2 and delivers phosphate to the ocean, fostering productivity and organic burial. During Snowballs, subaerial weathering ceases and only seafloor weathering operates. Volcanic outgassing of CO2 and reduced gases is constant in both modes. — Proceedings of the National Academy of Sciences

Repeated snowball–hothouse cycles within the Neoproterozoic Sturtian glaciation, Proceedings of the National Academy of Sciences

Astrobiology,