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Mysterious 'donut' structure is discovered hidden inside Earth's core - and it could unlock the secrets of our planet's protective magnetic field

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Scientists have uncovered a vast donut-shaped structure buried thousands of miles beneath our feet.

Researchers from the Australian National University used seismic waves generated by earthquakes to peer into the Earth's mysterious molten core.

By tracing the path of these waves through the planet, the researchers found a region a few hundred kilometres thick where they travelled two per cent slower than normal.

This donut-like structure runs parallel to the equator in a ring around the edge of the liquid outer core, and could be responsible for driving our planet's protective magnetic field.

Professor Hrvoje Tkalčić, lead author of the study, says: 'The magnetic field is a fundamental ingredient that we need for life to be sustained on the surface of our planet.'

Scientists have discovered a previously undetected donut-shaped region buried within the Earth which could be responsible for helping generate Earth's magnetic field (stock image)

Scientists have discovered a previously undetected donut-shaped region buried within the Earth which could be responsible for helping generate Earth's magnetic field (stock image)

Researchers found a region hundreds of kilometres thick and thousands of kilometres deep which wraps around the equator in a torus shape (labelled 'low velocity donut')

Researchers found a region hundreds of kilometres thick and thousands of kilometres deep which wraps around the equator in a torus shape (labelled 'low velocity donut')

The Earth is made up of four major layers: the surface crust, the semi-molten mantle, a liquid metal outer core, and a solid metal inner core.

When the movement of tectonic plates in the crust creates earthquakes, these produce vibrations that spread out through all the other layers of the Earth.

Using the worldwide network of seismographic stations, researchers can see how the waves spread and make predictions about the conditions below the surface.

Scientists usually only look at the big, powerful wavefronts which travel around the world in the first hour or so after an earthquake.

However, Professor Tkalčić and his co-author Dr Xiaolong Ma were able to detect this structure by studying the faint traces left behind by waves many hours after the initial tremor.

This method revealed that seismic waves travelling near the poles were moving faster than those near the equator.

The donut was detected by using measurements of seismic waves triggered by earthquakes around the world (pictured top) by analysing this data the researchers found a speed difference between the waves travelling by the poles (bottom left) and those travelling by the equator (bottom right)

The donut was detected by using measurements of seismic waves triggered by earthquakes around the world (pictured top) by analysing this data the researchers found a speed difference between the waves travelling by the poles (bottom left) and those travelling by the equator (bottom right) 

By comparing their results to different models of the Earth's interior, Professor Tkalčić and Dr Ma found that this was best explained by the presence of a vast underground 'torus', or donut-shaped, region.

They predict that this region is only found at low latitudes and runs parallel to the equator near the ceiling of the outer core where the liquid section meets the mantle.

'We don't know the exact thickness of the doughnut, but we inferred that it reaches a few hundred kilometres beneath the core-mantle boundary,' Professor Tkalčić says.

Thanks to this region's critical role, their discovery may also have profound implications for the study of life on Earth and other planets.

Earth's outer core has a radius of around 2,160 miles (3,480km) - making it slightly larger than Mars.

The best explanation for this data was the presence of an area of low-density material (pictured in red) sitting near the surface of the Earth's liquid outer core

The best explanation for this data was the presence of an area of low-density material (pictured in red) sitting near the surface of the Earth's liquid outer core 

The Earth's inner and outer cores are responsible for generating the planet's magnetic field, without which no life on Earth would be possible

The Earth's inner and outer cores are responsible for generating the planet's magnetic field, without which no life on Earth would be possible 

Mainly made of hot nickel and iron, convection currents coupled with the Earth's rotation force the liquid metal in this layer into long vertical vortices running in a north-south direction, like giant waterspouts.

It is the swirling currents of these liquid metals which act like the dynamo, powering the Earth's magnetic field.

Since this donut region has 'floated' to the top of the liquid outer core, it suggests that it could be rich in lighter elements like silicon, sulphur, oxygen, hydrogen or carbon.

Professor Tkalčić says: 'Our findings are interesting because this low velocity within the liquid core implies that we have a high concentration of light chemical elements in these regions that would cause the seismic waves to slow down.

The researchers believe that the donut -shaped region might be partially responsible for stirring the liquid metal in the outer core into the waterspout-like vortexes which generate the planet's magnetic field

The researchers believe that the donut -shaped region might be partially responsible for stirring the liquid metal in the outer core into the waterspout-like vortexes which generate the planet's magnetic field 

The Earth's magnetic field (pictured) deflects the charged particles carried by solar wind which can destroy the DNA of living creatures

The Earth's magnetic field (pictured) deflects the charged particles carried by solar wind which can destroy the DNA of living creatures 

'These light elements, alongside temperature differences, help stir liquid in the outer core.'

Without that stirring motion to drive the planet's interior dynamo, the Earth's magnetic field might not have formed.

Without the magnetic field, the planet's surface would be exposed to a constant bombardment of charged particles from the sun which can destroy the DNA of living creatures.

This donut-shaped region, therefore, might be a critical piece of the puzzle which explains why life has developed on Earth and what we might look for in habitable planets elsewhere.

Dr Tkalčić concludes: 'Our results could promote more research about the magnetic field on both Earth and other planets.'

EARTH'S LIQUID IRON CORE CREATES THE MAGNETIC FIELD

Our planet's magnetic field is believed to be generated deep down in the Earth's core.

Nobody has ever journeyed to the centre of the Earth, but by studying shockwaves from earthquakes, physicists have been able to work out its likely structure.

At the heart of the Earth is a solid inner core, two thirds of the size of the moon, made mainly of iron. 

At 5,700°C, this iron is as hot as the Sun's surface, but the crushing pressure caused by gravity prevents it from becoming liquid.

Surrounding this is the outer core there is a 1,242 mile (2,000 km) thick layer of iron, nickel, and small quantities of other metals. 

The metal here is fluid, because of the lower pressure than the inner core.

Differences in temperature, pressure and composition in the outer core cause convection currents in the molten metal as cool, dense matter sinks and warm matter rises.

The 'Coriolis' force, caused by the Earth's spin, also causes swirling whirlpools.

This flow of liquid iron generates electric currents, which in turn create magnetic fields.

Charged metals passing through these fields go on to create electric currents of their own, and so the cycle continues.

This self-sustaining loop is known as the geodynamo.

The spiralling caused by the Coriolis force means the separate magnetic fields are roughly aligned in the same direction, their combined effect adding up to produce one vast magnetic field engulfing the planet.

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