This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility:

fact-checked

peer-reviewed publication

trusted source

written by researcher(s)

proofread

New unified theory shows how past landscapes drove the evolution of Earth's rich diversity of life

Landscape dynamics determine the evolution of biodiversity on Earth
Sediment flux to the oceans and diversity of marine animal families over the past 540 million years. The Pearson coefficient of 0.88 indicates a strong positive correlation between the two variables. Credit: Nature

Earth's surface is the living skin of our planet—it connects the physical, chemical and biological systems.

Over , this surface evolves. Rivers fragment the landscape into an environmentally diverse range of habitats. These rivers also transfer sediments from the mountains to the continental plains and ultimately the oceans.

The idea that landscapes have influenced the trajectory of life on our planet has a long history, dating back to the early 19th century scientific narratives of German polymath Alexander von Humboldt. While we've learnt more since then, many aspects of biodiversity evolution remain enigmatic. For example, it's still unclear why there is a 100-million-year gap between the explosion of and the development of plants on continents.

In research published in Nature today, we propose a new theory that relates the evolution of biodiversity over the past 540 million years to "pulses" controlled by past landscapes.

10 years of computational time

Our simulations are based on an open-source code released as part of a Science paper published earlier this year.

To drive the evolution of the landscape through space and time in our , we used a series of reconstructions for what the climate and tectonics were like in the past.

We then compared the results of our global simulations with reconstructions of marine and continental biodiversity over the past 540 million years.

To perform our , we took advantage of Australia's National Computational Infrastructure running on several hundreds of processors. The combined simulations presented in our study are equivalent to ten years of computational time.

Marine life and river sediment were closely linked

In our model, we discovered that the more sediment rivers carried into the oceans, the more the sea life diversified (a positive correlation). You can see this tracked by the red line in the chart below.

As the continents weather, rivers don't just carry sediment into the oceans, they also bring a large quantity of nutrients. These nutrients, such as carbon, nitrogen and phosphorus, are essential to the biological cycles that move vital elements through all living things.

This is why we think rivers delivering more or less nutrients to the ocean—on a geological timescale of millions of years—is related to the diversification of marine life.

Perhaps even more surprisingly, we found that episodes of mass extinctions in the oceans happened shortly after significant decreases in sedimentary flow. This suggests that a lack or deficiency of nutrients can destabilize biodiversity and make it vulnerable to catastrophic events (like asteroid impacts or volcanic eruptions).

Landscapes also drove the diversity of plants

On the continents, we designed a variable that integrates sediment cover and landscape ruggedness to describe the continents' capacity to host diverse species.

Here we also found a striking correlation (see below) between our variable and plant diversification for the past 400 million years. This highlights how changes in landscape also have a strong influence on species diversifying on land.

We hypothesize that as Earth's surface was gradually covered with thicker soil, richer in nutrients deposited by , plants could develop and diversify with more elaborate root systems.

As plants slowly expanded across the land, the planet ended up hosting varied environments and habitats with favorable conditions for plant evolution, such as the emergence of flowering plants some 100 million years ago.

A living planet

Overall, our findings suggest the diversity of life on our planet is strongly influenced by dynamics. At any given moment, Earth's landscapes determine the maximum number of different species continents and oceans can support.

This shows it's not just tectonics or climates, but their interactions that determine the long-term evolution of biodiversity. They do this through sediment flows and changes to the landscapes at large.

Our findings also show that biodiversity has always evolved at the pace of plate tectonics. That's a pace incomparably slower than the current rate of extinction caused by human activity.

More information: Tristan Salles et al, Landscape dynamics and the Phanerozoic diversification of the biosphere, Nature (2023). DOI: 10.1038/s41586-023-06777-z

Journal information: Nature , Science

Provided by The Conversation

This article is republished from The Conversation under a Creative Commons license. Read the original article.The Conversation

Citation: New unified theory shows how past landscapes drove the evolution of Earth's rich diversity of life (2023, December 2) retrieved 4 December 2023 from https://phys.org/news/2023-11-theory-landscapes-drove-evolution-earth.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

Landscape dynamics determine the evolution of biodiversity on Earth, research reveals

96 shares

Feedback to editors