Australian Sky & Telescope - April 2018

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CRUCIAL OFFSET (TOP):

SKY & TELESCOPE /

LEAH TISCIONE; (BOTTOM): ESA / DTU SPACE; FAST CURRENT: ESA / AOES MEDIALAB

field strength more precisely than ever before. Measurements
taken by the European Space Agency’s three orbiting Swarm
satellites, combined with earlier data from the CHAMP
(Challenging Minisatellite Payload) and Ørsted spacecraft,
show that the field strength rose 2% over Asia and fell 3.5%
over North America from 1999 to 2016. And that broad
intensity dip south of the equator, known as the South
Atlantic Anomaly (see panel at left), is moving 20 km
westward each year and continues to weaken.
These local variations demonstrate that Earth’s magnetic
field is far more complicated than a simple dipole. Chaotic,
turbulent fluid motions in the outer core drag regions of
strong and weak fields around. These movements concentrate
magnetic field lines in some areas — at high latitudes, for
example — and thin them in other areas, such as the South
Atlantic. Swarm researcher Chris Finlay (Technical University
of Denmark) points out that these chaotic motions explain
why an extended region of weaker field is currently being
pulled westward toward the Americas, while regions of
stronger field are converging near Asia.
Swarm data enabled scientists to identify a ‘jet stream’
of molten iron in the outer core that is flowing westward at
about 40 km per year. This unexpected feature lies mostly
under Alaska and Siberia. The stream appears to be moving
patches of strong magnetism at high northern latitudes,
leading to the local changes seen at the surface. It’s uncertain
how much the jet stream is connected to the wandering of
the north magnetic pole, and whether processes at lower
latitudes are also contributing.
And superposed on top of these small-scale changes is the
general weakening trend in the global field over the past 175
years, leading to speculation that we could be heading toward
a reversal.

The ultimate flip-flop
Reversals are clearly documented in the paleomagnetic
record, particularly in sequences of seafloor rocks created
along tectonic spreading centres. These planet-wide records
confirm that Earth’s magnetic field has been flip-flopping
for hundreds of millions of years. But the reversal rate has
changed drastically over very long time scales.
For example, there are no recorded reversals from 120
million to 83 million years ago, one of three such ‘supercrons’
dating back 550 million years. Over the past few tens of
millions of years, the reversals have occurred about once every
250,000 years on average. But they’re inherently unpredictable
— the last major reversal was 780,000 years ago — making it
natural to wonder if our planet is long overdue for a flip-flop.
Scientists have not directly observed a reversal in action,
so it’s not entirely clear what happens. Still, they generally
agree that the field strength doesn’t just drop to zero and then
ramp back up. Instead, the dipolar field will probably break
down into many small-scale localised patches. Bundles of
magnetic field lines should intersect the surface in numerous

SCRUCIAL OFFSETTop:Earth’s magnetic field is strongly
dipolar,asifanenormousbarmagnetlaynearitsmiddle.But
thefieldistiltedslightlyandoffsetfromEarth’scentre.Above:
This snapshot of the strength of the magnetic field at Earth’s
surfaceinJune2014revealsanespeciallyweakareabetween
SouthAmericaandAfrica,knownastheSouthAtlanticAnomaly,
producedbythedipolefield’soffsetfromEarth’scentre.

SFAST CURRENTESA’s Swarm satellites have discovered a ‘jet
stream’movingwestwardinEarth’sliquidoutercore. The molten
current appears to be gradually speeding up.

Rotation
axis

Inner
radiation
belt Outer
radiation
belt

South Atlantic Anomaly

Dipole offset
from centre
by 500 km

Magnetic
axis

S

N

FieldStrengthatSurface(nanoteslas)

20,000 30,000 40,000 50,000 60,

Swarm
spacecraft

‘J e t s t r e a m’
in outer core

South
Atlantic
Anomaly

FIELD FLIP AHEAD?

16 AUSTRALIAN SKY & TELESCOPE April 2018

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