The magnetic North Pole is hurtling towards Siberia so quickly scientists have had to release new data a year ahead of schedule to keep navigation systems working properly
- World Magnetic Model (WMM) gives compasses the means to navigate north
- WMM provides a five year forecast of changes to the Earth's magnetic field
- The North Pole is moving so rapidly that current estimates weren't accurate
- Monday's update showed the magnetic north is leaving the Canadian Arctic towards Siberia at a speed of around 34 miles (55km) per year
The Arctic North Pole is only warmer because it is no longer the actual North Pole, that is moving at 55 km per year into Siberia. More wobble too and when does this all get critical, well on present calculations 2023 to 2026 when the magnetic focus moves into the weaker field lines and the acceleration of the magnetic movement really speeds up weakening the magnetosphere and exposing the Earth to more Cosmic radiation, cloud cover and exposure to Solar storms as we move away from Grand Solar Minimum.
What does that mean? Power outages, more disruption of satellite communications and crop harvest failures more widely as regions change climate pattern, higher food prices, the rich can afford it the others will just have to eat cake (cattle feed – an olde English joke).
Earth's magnetic North Pole has been wildly shifting towards Russia so quickly that scientists have been forced to publish an update on its actual location a year early.
The World Magnetic Model (WMM) enables compasses to point north and is used in navigation systems. Its latest update revealed the North Magnetic Pole is wandering about 34 miles a year. It crossed the international dateline in 2017 and is leaving the Canadian Arctic on its way to Siberia.
This is causing a navigational nightmare for compasses in smartphones, boats and for airport navigators as well as in some consumer electronics, and WMM was forced to update a year early in order to keep it accurate.
Earth's north magnetic pole has been drifting so fast in the last few decades that scientists say that past estimates are no longer accurate enough for precise navigation. The World Magnetic Model was updated on Monday, showing it is wandering about 34 miles (55 km) a year
WMM provides a five year forecast of changes to the Earth's magnetic field. The US and UK tend to update the location of the North Magnetic Pole every five years in December, but this update came early because of the pole's faster movement.
It had been hoped that the updated model could be released even earlier, last month, but it was held up by the recent shutdown in the US government, which oversees the project along with the British Geological Survey in Edinburgh, Scotland. Turbulence in in the planet's core, where the motion generates an electric field, has caused the field to change in systems described as 'akin to weather'.
Airplanes and boats also rely on magnetic north, usually as backup navigation, said University of Colorado geophysicist Dr Arnaud Chulliat, lead author of the WMM.
The military depends on where magnetic north is for navigation and parachute drops, while NASA, the Federal Aviation Administration and US Forest Service also use it. GPS is not affected because it's satellite-based.
Airport runway names are also based on their direction toward magnetic north and their names change when the poles moved.
For example, the airport in Fairbanks, Alaska, renamed a runway 1L-19R to 2L-20R in 2009.
The World Magnetic Model (WMM) enables compasses to point north and is used in navigation systems and was updated to keep it accurate. The update, released on Monday, showed that the magnetic north is leaving the Canadian Arctic on its way to Siberia
Since 1831 when it was first measured in the Canadian Arctic it has moved about 1400 miles (2300 km) towards Siberia.
Its speed jumped from about 9 mph (15 kph) to 34 mph (55 kph) since 2000.
The reason is turbulence in Earth's liquid outer core. There is a hot liquid ocean of iron and nickel in the planet's core where the motion generates an electric field, said University of Maryland geophysicist Dr Daniel Lathrop.
Dr Lathrop, who who wasn’t part of the team monitoring the magnetic north pole said: 'It has changes akin to weather. We might just call it magnetic weather.'
In general Earth's magnetic field is getting weaker, leading scientists to say that it will eventually flip, where north and south pole changes polarity, like a bar magnet flipping over.
It has happened numerous times in Earth's past, but not in the last 780,000 years.
'It's not a question of if it's going to reverse, the question is when it's going to reverse,' Dr Lathrop said.
When it reverses, it won't be like a coin flip, but take 1,000 or more years, experts said.
Dr Lathrop sees a flip coming sooner rather than later because of the weakened magnetic field and an area over the South Atlantic has already reversed beneath Earth's surface.
That could bother some birds that use magnetic fields to navigate. And an overall weakening of the magnetic field isn't good for people and especially satellites and astronauts.
Earth's magnetic field could FLIP sooner than previously thought and cause trillions of dollars in damage around the world
- When the magnetic poles flip, Earth’s protective magnetic field weakens
- This would wreak havoc on electrical grid, leave surface exposed to radiation
- Researchers found that field reversals can happen more rapidly than thought
Scientists in recent years have predicted that Earth’s magnetic field could be gearing up to ‘flip’ – a shift in which the magnetic south pole would become magnetic north, and vice versa.
Such an event could have catastrophic effects, wreaking havoc on the electric grid and leaving life at the surface exposed to higher amounts of solar radiation.
While it’s previously been thought that these reversals take place at intervals of hundreds of thousands of years, a new study suggests it could happen in just a matter of centuries.
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Scientists in recent years have predicted that Earth’s magnetic field could be gearing up to ‘flip’ – a shift in which the magnetic south pole would become magnetic north, and vice versa. Earth's magnetic field is illustrated above
Scientists estimate Earth’s North and South magnetic poles flip every 200,000-300,000 years.
But, it’s been roughly 780,000 years since the last such event, causing many to suspect we’re overdue.
When the magnetic poles flip, Earth’s protective magnetic field weakens, leaving its inhabitants at higher risk from the effects of space weather.
‘Earth’s magnetic field, which has existed for at least 3.45 billion years, provides a shield from the direct impact of solar radiation,’ said Professor Roberts from the ANU Research School of Earth Sciences.
‘Even with Earth’s strong magnetic field today, we’re still susceptible to solar storms that can damage our electricity-based society.’
In the new study, researchers at the Australian National University analyzed the paleomagnetic record from 107,000 to 91,000 years ago by analyzing a stalagmite from a cave in southwestern China.
The team conducted magnetic analysis and radiometric dating on the meter-long sample, revealing the behaviour of the ancient magnetic field.
And, they found the magnetic field experienced a rapid shift over the span of about two centuries, decreasing in strength by about 90 percent when a field reversal occurred.
In the new study, researchers at the Australian National University analyzed the paleomagnetic record from 107,000 to 91,000 years ago by analyzing a stalagmite from a cave in southwestern China
‘Hopefully such an event is a long way in the future and we can develop future technologies to avoid huge damage, where possible, from such events,’ Professor Roberts said.
The study suggests Earth’s magnetic field is a lot more unpredictable than suspected, the researchers say.
‘The record provides important insights into ancient magnetic field behaviour,’ Professor Roberts said, ‘which has turned out to vary much more rapidly than previously thought.’
Earth's magnetic poles could be about to FLIP: Experts warn the reversal could cause widespread blackouts and make parts of the world 'uninhabitable'
- Earth's magnetic field has weakened by 15 per cent over the last 200 years
- This could be a sign that the planet's north and south poles are about to flip
- If this happens, solar winds could punch holes into the Earth's ozone layer
- This could damage power grids, affect weather and increase cancer rates
- Daniel Baker, from the University of Colorado, Boulder, says that parts of the planet will become uninhabitable during a reversal
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The Earth has a fierce molten core that generates a magnetic field capable of defending our planet against devastating solar winds.
The protective field extends thousands of miles into space and its magnetism affects everything from global communication to power grids.
But this magnetic field, so important to life on Earth, has weakened by 15 per cent over the last 200 years.
And this, scientists claim, could be a sign that the Earth’s poles are about to flip.
In a new report, Daniel Baker, director of the Laboratory for Atmospheric and Space Physics at the University of Colorado, Boulder, claims there are signs of a reversal.
He says if this reversal happens, it is likely to render some areas of the planet 'uninhabitable' by knocking out power grids.
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His comments were made in an in-depth Undark report written by Alanna Mitchell, who has a new book about the topic titled 'The Spinning Magnet: The Electromagnetic Force that Created the Modern World and Could Destroy It',
Mitchell writes: 'The dangers: devastating streams of particles from the sun, galactic cosmic rays, and enhanced ultraviolet B rays from a radiation-damaged ozone layer, to name just a few of the invisible forces that could harm or kill living creatures.'
Historically, Earth’s North and South magnetic poles have flipped every 200,000 or 300,000 years.
However a flip is currently overdue as the last one was about 780,000 year ago.
The latest satellite data, from the European Space Agency’s Swarm trio which monitors the Earth's magnetic field, suggests a flip may be imminent.
The satellites allow researchers to study changes building at the Earth’s core, where the magnetic field is generated.
Their observations suggest molten iron and nickel are draining energy out of the Earth’s core near where the magnetic field is generated.
While scientists aren't sure why exactly this happens, they describe it as a 'restless activity' that suggests the magnetic field is preparing to flip.
If a switch happens, we would be exposed to solar winds capable of punching holes into the ozone layer.
The Earth's protective field extends thousands of miles into space and its magnetism affects everything from global communication to animal migration and weather patterns
‘This is serious business’, Richard Holme, Professor of Earth, Ocean and Ecological Sciences at Liverpool University told MailOnline.
‘Imagine for a moment your electrical power supply was knocked out for a few months – very little works without electricity these days.’
The Earth's climate would change drastically. In fact, a Danish study believes global warming is directly related to the magnetic field rather than CO2 emissions.
The study claimed that the planet is experiencing a natural period of low cloud cover due to fewer cosmic rays entering the atmosphere.
Radiation at ground level would also increase, with some estimates suggesting overall exposure to cosmic radiation would double causing more deaths from cancer.
Researchers predict that in the event of a flip, every year a hundred thousand people would die from the increased levels of space radiation.
'Radiation could be 3-5 times greater than that from the man-made ozone holes. Furthermore, the ozone holes would be larger and longer-lived,' said Dr Colin Forsyth from the Mullard Space Science Laboratory at UCL.
The magnetosphere is a large area around the Earth produced by the planet's magnetic field. It presence means that charged particles of the solar wind are unable to cross the magnetic field lines and are deflected around the Earth
The magnetosphere is a large area around the Earth produced by the planet’s magnetic field.
Its presence means that charged particles of the solar wind are unable to cross the magnetic field lines and are deflected around the Earth
Scientists have discovered that ancient pots can act as a magnetic time capsule.
This is because they contain an iron-based mineral called magnetite. When pots form, the magnetite minerals align with the Earth’s magnetic field, just like compass needles.
The Earth's magnetic field is generated in the very hot molten core of the planet. Scientists believe Mars used to have a magnetic field similar to that on Earth which protected its atmosphere
By examining pottery from prehistory to modern times, scientists have discovered just how dramatically the field has changed in the last few centuries.
They’ve found that Earth’s magnetic field is in a permanent state of flux.
Magnetic north drifts and every few hundred thousand years the polarity flips so a compass would point south instead of north.
If the magnetic field continues to decline, over billions of years, Earth could end up like Mars - a once oceanic world that has become a dry, barren planet incapable of supporting life.
But scientists claim the rate of decline is too fast for the Earth’s core to simply burn out.
Instead, the story told by ancient pottery suggests the Earth's poles could be about to undergo another flip.
According to the British Geological Survey, the Earth's magnetic field has on average four or five reversals in polarity every million years and we’re now overdue a similar event.
‘At the moment, we cannot accurately determine whether or not the Earth’s field is about to flip,’ said Dr Forsyth. ‘We have only been recording the Earth’s field for around 170 years; about 1-15 per cent of the time a flip is expected to take.’
If a flip occurs, it would cause the Earth’s magnetic shield to be weakened for thousands of years, opening up our defences and causing cosmic radiation to get through.
'We have a double layer defence shield,' said Jim Wild a space scientists at Lancaster University.
'Space is full ofstuff that’s not great for biological tissue. If we didn’t have an atmosphere,that stuff would be hitting us. It’s the magnetic field protects atmospherefrom the solar wind.'
Not all of the effects of a weak magnetic field will be bad. The much sought-after spectacle of an aurora would be visible every night all over the Earth as solar winds hit the atmosphere
The 'out of Africa' theory that explains why the Earth's magnetic poles may soon switch
- The Earth's magnetic field protects life from harmful solar radiation
- Far from being constant, this field is continuously changing
- Geomagnetic reversals occur a few times every million years on average
- And when the field flips it also tends to become very weak
- The strength of Earth’s magnetic field has been decreasing for the last 160 years
- It's happening in a patch centered in a huge expanse extending from Zimbabwe to Chile, known as the South Atlantic Anomaly
The Earth is blanketed by a magnetic field.
It’s what makes compasses point north, and protects our atmosphere from continual bombardment from space by charged particles such as protons.
Without a magnetic field, our atmosphere would slowly be stripped away by harmful radiation, and life would almost certainly not exist as it does today.
The alteration in the magnetic field during a reversal will weaken its shielding effect, allowing heightened levels of radiation on and above the Earth's surface
You might imagine the magnetic field is a timeless, constant aspect of life on Earth, and to some extent you would be right.
But Earth’s magnetic field actually does change.
Every so often – on the order of several hundred thousand years or so – the magnetic field has flipped.
North has pointed south, and vice versa.
And when the field flips it also tends to become very weak.
What currently has geophysicists like us abuzz is the realization that the strength of Earth’s magnetic field has been decreasing for the last 160 years at an alarming rate.
This collapse is centered in a huge expanse of the Southern Hemisphere, extending from Zimbabwe to Chile, known as the South Atlantic Anomaly.
The magnetic field strength is so weak there that it’s a hazard for satellites that orbit above the region – the field no longer protects them from radiation which interferes with satellite electronics.
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
And the field is continuing to grow weaker, potentially portending even more dramatic events, including a global reversal of the magnetic poles.
Such a major change would affect our navigation systems, as well as the transmission of electricity.
The spectacle of the northern lights might appear at different latitudes.
And because more radiation would reach Earth’s surface under very low field strengths during a global reversal, it also might affect rates of cancer.
We’re turning to some perhaps unexpected data sources, including 700-year-old African archaeological records, to puzzle it out.
Earth’s magnetic field is created by convecting iron in our planet’s liquid outer core.
From the wealth of observatory and satellite data that document the magnetic field of recent times, we can model what the field would look like if we had a compass immediately above the Earth’s swirling liquid iron core.
These analyses reveal an astounding feature: There’s a patch of reversed polarity beneath southern Africa at the core-mantle boundary where the liquid iron outer core meets the slightly stiffer part of the Earth’s interior.
In this area, the polarity of the field is opposite to the average global magnetic field.
If we were able to use a compass deep under southern Africa, we would see that in this unusual patch north actually points south.
This patch is the main culprit creating the South Atlantic Anomaly.
In numerical simulations, unusual patches similar to the one beneath southern Africa appear immediately prior to geomagnetic reversals.
The poles have reversed frequently over the history of the planet, but the last reversal is in the distant past, some 780,000 years ago.
The rapid decay of the recent magnetic field, and its pattern of decay, naturally raises the question of what was happening prior to the last 160 years.
In archaeomagnetic studies, geophysicists team with archaeologists to learn about the past magnetic field.
For example, clay used to make pottery contains small amounts of magnetic minerals, such as magnetite.
When the clay is heated to make a pot, its magnetic minerals lose any magnetism they may have held.
Upon cooling, the magnetic minerals record the direction and intensity of the magnetic field at that time.
The location of the South Atlantic Anomaly (pictured), an area extending from Zimbabwe to Chile where the Earth's magnetic field is so weak that it's a hazard for satellites that orbit above the region - the field no longer protects them from radiation which interferes with satellite electronics
If one can determine the age of the pot, or the archaeological site from which it came (using radiocarbon dating, for instance), then an archaeomagnetic history can be recovered.
Using this kind of data, we have a partial history of archaeomagnetism for the Northern Hemisphere.
In contrast, the Southern Hemisphere archaeomagnetic record is scant.
In particular, there have been virtually no data from southern Africa – and that’s the region, along with South America, that might provide the most insight into the history of the reversed core patch creating today’s South Atlantic Anomaly.
But the ancestors of today’s southern Africans, Bantu-speaking metallurgists and farmers who began to migrate into the region between 2,000 and 1,500 years ago, unintentionally left us some clues.
These Iron Age people lived in huts built of clay, and stored their grain in hardened clay bins.
As the first agriculturists of the Iron Age of southern Africa, they relied heavily on rainfall.
The communities often responded to times of drought with rituals of cleansing that involved burning mud granaries.
Clay used to make pottery contains small amounts of magnetic minerals, such as magnetite. When the clay is heated to make a pot, its magnetic minerals lose any magnetism they may have held. Upon cooling, the magnetic minerals record the direction and intensity of the magnetic field at that time. If one can determine the age of the pot, or the archaeological site from which it came (using radiocarbon dating, for instance), then an archaeomagnetic history can be recovered. The researchers teamed up with archaeologists to sample Iron Age village sites that dot the Limpopo River Valley, bordered today by Zimbabwe to the north, Botswana to the west and South Africa to the south
This somewhat tragic series of events for these people was ultimately a boon many hundreds of years later for archaeomagnetism.
Just as in the case of the firing and cooling of a pot, the clay in these structures recorded Earth’s magnetic field as they cooled.
Because the floors of these ancient huts and grain bins can sometimes be found intact, we can sample them to obtain a record of both the direction and strength of their contemporary magnetic field.
Each floor is a small magnetic observatory, with its compass frozen in time immediately after burning.
With our colleagues, we’ve focused our sampling on Iron Age village sites that dot the Limpopo River Valley, bordered today by Zimbabwe to the north, Botswana to the west and South Africa to the south.
Sampling at Limpopo River Valley locations has yielded the first archaeomagnetic history for southern Africa between A.D. 1000 and 1600.
What we found reveals a period in the past, near A.D. 1300, when the field in that area was decreasing as rapidly as it is today.
Then the intensity increased, albeit at a much slower rate.
The occurrence of two intervals of rapid field decay – one 700 years ago and one today – suggests a recurrent phenomenon.
Could the reversed flux patch presently under South Africa have happened regularly, further back in time than our records have shown?
Sampling at Limpopo River (pictured) Valley locations has yielded the first archaeomagnetic history for southern Africa between A.D. 1000 and 1600. What the researchers found reveals a period in the past, near A.D. 1300, when the field in that area was decreasing as rapidly as it is today. Then the intensity increased, albeit at a much slower rate. The occurrence of two intervals of rapid field decay – one 700 years ago and one today – suggests a recurrent phenomenon
If so, why would it occur again in this location?
Over the last decade, researchers have accumulated images from the analyses of earthquakes’ seismic waves.
As seismic shear waves move through the Earth’s layers, the speed with which they travel is an indication of the density of the layer.
Now we know that a large area of slow seismic shear waves characterizes the core mantle boundary beneath southern Africa.
This particular region underneath southern Africa has the somewhat wordy title of the African Large Low Shear Velocity Province.
While many wince at the descriptive but jargon-rich name, it is a profound feature that must be tens of millions of years old.
While thousands of kilometers across, its boundaries are sharp.
Interestingly, the reversed core flux patch is nearly coincident with its eastern edge.
The fact that the present-day reversed core patch and the edge of the African Large Low Shear Velocity Province are physically so close got us thinking.
A weakened magnetosphere will also mean that more aurora lights will be seen on Earth as solar winds hit the atmosphere
We’ve come up with a model linking the two phenomena.
We suggest that the unusual African mantle changes the flow of iron in the core underneath, which in turn changes the way the magnetic field behaves at the edge of the seismic province, and leads to the reversed flux patches.
We speculate that these reversed core patches grow rapidly and then wane more slowly.
Occasionally one patch may grow large enough to dominate the magnetic field of the Southern Hemisphere – and the poles reverse.
The conventional idea of reversals is that they can start anywhere in the core.
Our conceptual model suggests there may be special places at the core-mantle boundary that promote reversals.
We do not yet know if the current field is going to reverse in the next few thousand years, or simply continue to weaken over the next couple of centuries.
But the clues provided by the ancestors of modern-day southern Africans will undoubtedly help us to further develop our proposed mechanism for reversals.
If correct, pole reversals may be 'Out of Africa.'
Scientists understand that Earth's magnetic field has flipped its polarity many times over the millennia. In other words, if you were alive about 800,000 years ago, and facing what we call north with a magnetic compass in your hand, the needle would point to 'south.' This is because a magnetic compass is calibrated based on Earth's poles. The N-S markings of a compass would be 180 degrees wrong if the polarity of today's magnetic field were reversed. Many doomsday theorists have tried to take this natural geological occurrence and suggest it could lead to Earth's destruction. But would there be any dramatic effects? The answer, from the geologic and fossil records we have from hundreds of past magnetic polarity reversals, seems to be 'no.'
Reversals are the rule, not the exception. Earth has settled in the last 20 million years into a pattern of a pole reversal about every 200,000 to 300,000 years, although it has been more than twice that long since the last reversal. A reversal happens over hundreds or thousands of years, and it is not exactly a clean back flip. Magnetic fields morph and push and pull at one another, with multiple poles emerging at odd latitudes throughout the process. Scientists estimate reversals have happened at least hundreds of times over the past three billion years. And while reversals have happened more frequently in "recent" years, when dinosaurs walked Earth a reversal was more likely to happen only about every one million years.
Sediment cores taken from deep ocean floors can tell scientists about magnetic polarity shifts, providing a direct link between magnetic field activity and the fossil record. The Earth's magnetic field determines the magnetization of lava as it is laid down on the ocean floor on either side of the Mid-Atlantic Rift where the North American and European continental plates are spreading apart. As the lava solidifies, it creates a record of the orientation of past magnetic fields much like a tape recorder records sound. The last time that Earth's poles flipped in a major reversal was about 780,000 years ago, in what scientists call the Brunhes-Matuyama reversal. The fossil record shows no drastic changes in plant or animal life. Deep ocean sediment cores from this period also indicate no changes in glacial activity, based on the amount of oxygen isotopes in the cores. This is also proof that a polarity reversal would not affect the rotation axis of Earth, as the planet's rotation axis tilt has a significant effect on climate and glaciation and any change would be evident in the glacial record.
Earth's polarity is not a constant. Unlike a classic bar magnet, or the decorative magnets on your refrigerator, the matter governing Earth's magnetic field moves around. Geophysicists are pretty sure that the reason Earth has a magnetic field is because its solid iron core is surrounded by a fluid ocean of hot, liquid metal. This process can also be modeled with supercomputers. Ours is, without hyperbole, a dynamic planet. The flow of liquid iron in Earth's core creates electric currents, which in turn create the magnetic field. So while parts of Earth's outer core are too deep for scientists to measure directly, we can infer movement in the core by observing changes in the magnetic field. The magnetic north pole has been creeping northward – by more than 600 miles (1,100 km) – since the early 19th century, when explorers first located it precisely. It is moving faster now, actually, as scientists estimate the pole is migrating northward about 40 miles per year, as opposed to about 10 miles per year in the early 20th century.
Another doomsday hypothesis about a geomagnetic flip plays up fears about incoming solar activity. This suggestion mistakenly assumes that a pole reversal would momentarily leave Earth without the magnetic field that protects us from solar flares and coronal mass ejections from the sun. But, while Earth's magnetic field can indeed weaken and strengthen over time, there is no indication that it has ever disappeared completely. A weaker field would certainly lead to a small increase in solar radiation on Earth – as well as a beautiful display of aurora at lower latitudes - but nothing deadly. Moreover, even with a weakened magnetic field, Earth's thick atmosphere also offers protection against the sun's incoming particles.
The science shows that magnetic pole reversal is – in terms of geologic time scales – a common occurrence that happens gradually over millennia. While the conditions that cause polarity reversals are not entirely predictable – the north pole's movement could subtly change direction, for instance – there is nothing in the millions of years of geologic record to suggest that any of the 2012 doomsday scenarios connected to a pole reversal should be taken seriously. A reversal might, however, be good business for magnetic compass manufacturers.
The magnetic field shields Earth from some dangerous radiation, Dr Lathrop said.
Scientists in recent years have predicted that Earth's magnetic field could be gearing up to 'flip' – a shift in which the magnetic south pole would become magnetic north, and vice versa. Earth's magnetic field is illustrated above