2.4-Million-Year Connection Between Earth and Mars Found

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2.4-Million-Year Connection Between Earth and Mars Found

University of Sydney

Geoscientists from Sydney and Sorbonne have embarked on an extraordinary journey, linking the dance of Earth and Mars to the pulsating life of our deep oceans. They have identified a 2.4-million-year cycle, a cosmic rhythm dictating the ebb and flow of ancient seas, shaping climates and challenging our understanding of Earth’s hidden underwater currents.

A Discovery of Long-distance Planetary Connections

Scientists from the Universities of Sydney and Sorbonne University have used the geological record of the deep sea to discover a connection between the orbits of Earth and Mars, past global warming patterns and the speeding up of deep ocean circulation.

They discovered a surprising 2.4-million-year cycle where deep currents wax and wane which, in turn, is linked to periods of increased solar energy and a warmer climate.

The study, published in Nature Communications, tackles the questions of how geological-timescale climate change affects ocean circulation and how this could help scientists to model future climates outcomes. The researchers looked to find if ocean-bottom currents become more vigorous or more sluggish in a warmer climate.

These cycles are not linked to the current rapid global warming caused by human greenhouse gas emissions.

Lead author ARC Future Fellow Dr Adriana Dutkiewicz from the University of Sydney EarthByte Group in the School of Geosciences and co-authors used more than half a century of scientific drilling data from hundreds of sites worldwide to understand the vigor of deep-sea currents through time.

In a collaboration with Professor Dietmar Müller (University of Sydney) and Associate Professor Slah Boulila (Sorbonne), Dr Dutkiewicz used the deep-sea sediment record to check for links between sedimentary shifts and changes in the Earth’s orbit.

They found that the vigor of deep-sea currents shifts in 2.4-million-year cycles.

These cycles are called “astronomical grand cycles”, predicted to occur due to the interactions of Earth and Mars orbits. However, evidence for this is rarely detected in the geological record.

Dr Dutkiewicz said:

“We were surprised to find these 2.4-million-year cycles in our deep-sea sedimentary data. There is only one way to explain them: they are linked to cycles in the interactions of Mars and Earth orbiting the Sun.”

Lead author Dr Adriana Dutkiewicz in the field. (University of Sydney)

Lead author Dr Adriana Dutkiewicz in the field. (University of Sydney)

Planetary Oceanic Influence

Co-author Professor Müller said:

“The gravity fields of the planets in the solar system interfere with each other and this interaction, called a resonance, changes planetary eccentricity, a measure of how close to circular their orbits are.”

For the Earth it means periods of higher incoming solar radiation and warmer climate in cycles of 2.4 million years. The researchers found that the warmer cycles correlate with an increased occurrence of breaks in the deep-sea record, related to more vigorous deep ocean circulation.

The study has identified that deep eddies were an important component of earlier warming seas. It is possible these could partly mitigate ocean stagnation some have predicted could follow a faltering AMOC (Atlantic Meridional Overturning Circulation) that drives the Gulf Stream and maintains temperate climates in Europe.

Professor Müller said: “We know there are at least two separate mechanisms that contribute to the vigor of deep-water mixing in the oceans. AMOC is one of them, but deep ocean eddies seem to play an important role in warm climates for keeping the ocean ventilated.

“Of course, this would not have the same effect as AMOC in terms of transporting water masses from low to high latitudes and vice-versa.”

These eddies are like giant whirlpools and often reach the abyssal seafloor, resulting in seafloor erosion and large sediment accumulations called contourites, akin to snowdrifts.

Dr Dutkiewicz said:

“Our deep-sea data spanning 65 million years suggest that warmer oceans have more vigorous deep circulation. This will potentially keep the ocean from becoming stagnant even if Atlantic Meridional Overturning Circulation slows or stops altogether.”

How the interplay between different processes driving deep-ocean dynamics and ocean life may play out in the future is still not well known, but the authors hope that their new results will help with building better climate models.

Top image: Earth’s distance to Mars varies between 55 and 400 million kilometers, but that doesn’t stop it influencing our oceans. (Photo not to scale)  Source: University of Sydney

The article, originally titled ‘Mars attracts: how Earth’s planetary interactions drive deep-sea circulation’ was first published by the University of Sydney.





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