A new study involving an international team of researchers has found that the evolution of land plants caused a sudden shift in the composition of Earth's continents.
The discovery was made by linking the fossil record of plants with archives of environmental change, and with records of the chemical composition of the Earth deep beneath our feet, over the past 700 million years.
In doing so, scientists have pinpointed a dramatic shift in the composition of rocks making up Earth’s continents that was driven by the primitive vegetation trapping mud on land, stopping it washing down rivers and out into the sea.
Dr Alex Brasier, from the University of Aberdeen’s School of Geosciences, is among the co-authors of the study which involved scientists from the universities of Southampton, Cambridge, Wuhan in China and Queen’s University in Canada. It has been published in the Nature Geoscience journal
He said: “The first land plants were simple, small things like mosses that lived in wet environments on land between about 450 and 420 million years ago during the Ordovician and Silurian Periods. Bigger plants with deeper roots that could live in drier environments evolved shortly after, in the Devonian Period.
“These primitive plants spread across the land, transforming what was once a Mars-like planet of barren rock into a world of life growing in organic-rich soils. Some of the most spectacular and important early land plant fossils on Earth are from the village of Rhynie in Aberdeenshire, where minerals precipitated from a hot-spring and fossilised their stems – together with other things that were living on the plants like the ancestors of insects - 407 million years ago”
Dr Brasier added that the study will inform upcoming examination of fossils originating from the small Aberdeenshire village of Rhynie, well known amongst palaeontologists for its spectacular fossils of 407-million-year-old primitive plants.
“We are now working with colleagues from Queen’s University on the chemistry of the rocks from the Rhynie hot-springs, where we hope to reveal more about this important fossil-preserving site and searching for further clues on how these early land plants changed the Earth.”
The proliferation of plants completely transformed Earth’s biosphere – those parts of the planet’s surface where life thrives – with small plants later evolving into trees, and paving the way for giant 2.5 metre long centipedes that left their footprints on the Isle of Arran in the coal swamps of the Carboniferous period, and later for the advent of dinosaurs.
The study’s lead author, Dr Christopher Spencer, Assistant Professor at Queen’s University, explained that plants caused fundamental changes to river systems, bringing about more meandering rivers and muddy floodplains, as well as thicker soils.
He added: “This shift was tied to the development of plant rooting systems that helped produce colossal amounts of mud (by breaking down rocks) and stabilised river channels, which locked up this mud for long periods.”
The team recognised that Earth’s surface and deep interior are linked by plate tectonics – rivers flush mud into the oceans, and this mud then gets dragged into the Earth’s molten interior at subduction zones where it gets melted to form new rocks.
“When these rocks crystallise, they trap in vestiges of their past history,” explained study co-author Dr Tom Gernon, Associate Professor of Earth Science at the University of Southampton. “So, we hypothesised that the evolution of plants should dramatically slow down the delivery of mud to the oceans, and that this feature should be preserved in the rock record – it’s that simple.”
To test this idea, the team studied a database of over five thousand zircon crystals formed in magmas at subduction zones – essentially ‘time capsules’ that preserve vital information on the chemical conditions that prevailed on Earth when they crystallised.
The team uncovered compelling evidence for a dramatic shift in the composition of rocks making up Earth’s continents, which neatly coincides with the onset of the first mud-trapping land plants.
Notably, the scientists also found that the chemical characteristics of zircon crystals generated at this time indicate a significant slowing down of sediment transfer to the oceans, just as they had hypothesised.
The researchers show that vegetation changed not only the surface of the Earth, but also the dynamics of melting in Earth’s mantle.
“It is amazing to think that the greening of the continents was felt in the deep Earth,” Dr Spencer said. “Hopefully this previously unrecognised link between the Earth’s interior and surface environment stimulates further study.”