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__Rule space October 19, 1996 space Rule

_Core Concerns_

_The hidden reaches of Earth are starting to reveal some of their secrets_

_By RICHARD MONASTERSKY_

_G_ary A. Glatzmaier gazed down on the world he had created and
decided it was good. Peering deep into the bowels of the planet, he
saw vast currents of molten iron alloy swirling at temperatures above
5,000 kelvins, nearly as hot as the surface of the sun. He watched for
40,000 years as the globe's magnetic field pulsated like the beating
of a heart. Deeper still, at the center, he beheld a spinning orb made
of solid iron almost as large as the moon.

This creation, forged from numbers and equations, is a virtual version
of Earth's metallic core. Glatzmaier, a geophysicist at Los Alamos
(N.M.) National Laboratory, constructed the extremely sophisticated
computer model to simulate the magnetic dynamo that churns away,
unseen, far below Earth's crust.

Five years ago, most geophysicists considered such representations
poor stand-ins for the real core -- the scientific equivalent of a
tone-deaf Elvis impersonator. In the last year, however, these models
have earned newfound respect by showing striking similarities to the
real thing. The simulation by Glatzmaier and his colleague Paul H.
Roberts of the University of California, Los Angeles scored a major
coup with its prediction that Earth's solid inner core spins out of
sync with the rest of the planet -- a feature verified 3 months ago by
seismologists (SN: 7/20/96, p. 36, [1]Putting a New Spin on Earth's
Core ).

Combined with recent advances in seismology, the computer models are
opening windows into Earth's hitherto impenetrable iron heart. This
new access gives scientists hope that they can finally tackle what
Einstein reputedly called one of the five greatest unsolved problems
in physics: the origin of the planet's magnetic field.

Although theorists have made great strides since Einstein offered that
challenge, geomagnetists still lack a firm understanding of how the
field forms and why it changes direction every few hundred thousand
years or so. "The mechanisms behind the magnetic field and behind the
reversals are still really mysterious. It's fair to say that this is
one of the grand intellectual challenges -- not just in the earth
sciences, but, I think, in all of the physical sciences," says Raymond
Jeanloz, a geophysicist at the University of California, Berkeley.

RedsTriRule

_A_ soft-spoken scientist most at home among his equations, Glatzmaier
declines any comparison with the creator in Genesis. It's interesting
to note, however, that Glatzmaier began his modeling work with the
sun, only later moving on to model Earth.

Initially, Glatzmaier simulated the sun's magnetic field, which arises
from the motion of ionized hydrogen and helium inside that star. The
branch of physics governing this realm is called magnetohydrodynamics,
a mouthful of a term that researchers often shorten to MHD.

After the sun, Glatzmaier studied Jupiter, the Kuwaiti oil fires, and
Earth's rocky mantle before finally turning to Earth's core. The
recent model -- a variation of the one developed for the sun --
simulates in three dimensions the currents of iron alloy flowing
within the core.

The planet's nucleus is believed to have formed early in Earth's
4.5-billion-year history, when molten iron and other heavy elements
sank deep into the planet. As this metallic soup cooled over the eons,
crystals of iron froze at the center, creating a solid iron core
inside the surrounding liquid alloy.

Over time, this process built an inner core 2,440 kilometers wide,
about one-fifth the diameter of the planet. The outer core of liquid
alloy spans 2,260 km from top to bottom and is composed of 90 percent
iron and 10 percent lighter elements, possibly oxygen and sulfur.

The slow cooling of the core, which continues today, is critical
because it stirs the iron alloy. Heat escaping from the top of the
outer core chills the upper layers of the outer core, causing the
material to sink. At the same time, iron crystals freeze and adhere to
the surface of the inner core, leaving behind material richer in the
lighter elements. This alloy floats to the surface of the outer core.

This movement of metallic fluids gave birth to Earth's geomagnetic
field, according to MHD theory. Basic physics teaches that moving
metals can produce an electric current if they pass through a
preexisting magnetic field. This principle underlies most electric
generators, which use heat to move turbines that carry wires past
magnets.

If magnetic fields were common in the early solar system, as
scientists believe, then convective flow in the outer core must have
created electric currents in the fluid iron. The process turned into a
self-sustaining dynamo, because electric currents produce their own
magnetic fields. Once the core started producing a magnetic field, the
continuous movement of the iron alloy would have maintained electric
currents in the outer core, thereby sustaining the geomagnetic field.

RedsTriRule

_P_hysicists had sketched out the general picture of this dynamo model
by the late 1950s, but the details of what goes on in the outer core
remain one of Earth's deepest secrets. What little is known about the
outer core comes from the portion of the geomagnetic field that
reaches Earth's surface. With its prominent north and south poles,
this field is roughly dipolar in orientation, as if it came from a
huge bar magnet buried inside the planet.

The simple exterior field -- the one that guides Boy and Girl Scouts,
airliners, and migrating birds -- is but a tiny fraction of the
magnetic field writhing within Earth's core. The portion one can sense
at Earth's surface comes only from the uppermost layer of the outer
core. The much more complex field generated deeper down is trapped
inside the outer core and never reaches the planet's exterior.

In fact, much of the field created in the upper layer of the outer
core also remains hidden. The toroidal portion of the field -- which
runs in circular east-west bands within the outer core -- does not
leak outside the core, so scientists cannot measure it. Only the
poloidal element -- which loops from one pole around to the other pole
-- extends to the planet's surface and into space.

While Earth conceals most of its field, a computer model is less
bashful. That's why Glatzmaier and Roberts have attempted to create a
virtual version of the geodynamo, which they run at the Pittsburgh
Supercomputing Center and at Los Alamos. They started by specifying
how quickly heat leaks out of the core, and then they let the MHD
equations govern how the liquid alloy responds. The flow patterns, as
they established themselves, generated electric currents and a
magnetic field.

"The question I wanted to answer was whether convection in the fluid
core could actually maintain the magnetic field -- a field that looks
like the Earth's magnetic field," says Glatzmaier. "People had assumed
it was happening that way, but it was never really demonstrated.
What's encouraging is that I'm getting a magnetic field that looks a
lot like Earth's in its strength and its structure."

The similarities extend beyond mere looks. The computer-fabricated
field migrates slowly to the west in a manner similar to that of the
actual field, whose features shift westward by roughly a degree each
decade.

The model represents a step forward, says Glatzmaier, because in most
previous attempts, researchers had prescribed the flow patterns rather
than letting them evolve in response to the magnetic field. The
earlier techniques used a short-cut that simplified the problem and
guaranteed a realistic outcome -- as if the tone-deaf Elvis
impersonator only lip-synced instead of actually singing.

"The less you specify in the model, the more you are able to learn. If
you specify everything, you can get something that looks just like the
Earth, but you will not understand why things happen because you have
specified the solution," says Glatzmaier.

Glatzmaier and Roberts let their model run through millennia of
simulated time, watching the magnetic field wither and then rebound,
all the while remaining dipolar. About 35,000 years into the
simulation (and after more than a year of real time), the dipolar
field nearly disappeared. For 1,000 virtual years the field
languished, with a confusing multitude of magnetic poles popping up
instead of fixed north and south poles. When the field eventually
recuperated, it was pointing in the opposite direction.

Here was a real triumph for Glatzmaier and Roberts. Their MHD model
had produced a geomagnetic reversal entirely on its own, without any
provocation from the experimenters.

"Our original motivation was not to simulate magnetic field reversals.
That seemed too much to hope for. So that was a nice surprise," says
Glatzmaier.

Graphic

_As the world turns over: In this computer simulation, the magnetic
field emanating from the core flipped upside down. Before the
reversal, poloidal magnetic field lines leave the north magnetic pole,
curve around the planet, and dive back into the south pole (left).
During the transition, the field becomes disorganized (middle) for
roughly 1,000 years and then reestablishes itself with the opposite
polarity (right). Lines wrapping around the core in east-west bands
indicate the toroidal magnetic field._

The two researchers published their reversal data in the Sept. 21,
1995 _Nature_. Although the model simulations have continued, with one
now exceeding 200,000 years in duration, Glatzmaier and Roberts have
not witnessed a second reversal.

That may be a good sign, since reversals of the actual geomagnetic
field usually occur only once every few hundred thousand years and
occasionally much less frequently. Still, with only one reversal under
their belts, the scientists cannot yet draw many conclusions about
what causes the process.

RedsTriRule

_T_he MHD model garnered even more attention last July, when two
seismologists reported that the solid inner core of the actual Earth
is spinning faster than the rest of the planet. Xiaodong Song and Paul
G. Richards of the Lamont-Doherty Earth Observatory in Palisades,
N.Y., who made the discovery, credited the MHD model for stimulating
their search.

Glatzmaier and Roberts had predicted the core's quick spin last year,
after studying the flow patterns of the iron alloy within their model.
The simulation revealed eastward-moving currents of fluid at the
bottom of the outer core, roughly analogous to the jet streams in the
atmosphere. These currents in the outer core, the scientists realized,
would put a magnetic torque on the inner core, forcing it to spin
slightly faster than the mantle and crust.

One of Glatzmaier and Roberts' chief competitors, Jeremy Bloxham of
Harvard University, has documented a similar torque within his MHD
model of the core. In the Harvard simulations, which began more
recently than the Los Alamos work, the core spins faster than the rest
of the planet on average, but it slows down for brief periods. "I
wouldn't be surprised if the rate changes with time," says Bloxham.

There may, however, be explanations besides magnetic torque for the
core's fast spin. Berkeley's Jeanloz notes that the rotation rate of
the entire Earth is slowing as a result of the friction caused by
lunar and solar tides. The deceleration of the inner core, however,
may lag behind that of the rest of the planet because the inner core
is separated from the mantle and crust by the fluid outer core.
According to this theory, the inner core is now rotating as quickly as
Earth's surface was spinning 60,000 to 100,000 years ago.

"We may be able to distinguish if one or the other of these ideas is
correct over the coming decades, if not years," says Jeanloz. If
magnetic torques are causing the discrepancy, seismologists monitoring
the inner core should see the rotation rate vary with time. If the
slowdown of Earth is to blame, then the rotation rate should change
little except for an extremely slow deceleration. Both of these
mechanisms may work together, says Jeanloz.

As seismologists continue to refine ways of detecting the inner core's
rotation, Glatzmaier, Roberts, and others work on improving the MHD
models of the core. At present, the models take shortcuts in
simulating fluid flow in the core. Because of computer limitations,
MHD models treat the iron alloy as being orders of magnitude more
viscous than the actual liquid core, which scientists think flows
about as easily as water. "We're hoping we're not doing too much harm
by making this approximation," says Glatzmaier.

These and other limitations had led many geophysicists to disregard
MHD models. The recent successes, however, have quieted critics and
forced them to start taking the models seriously.

"The types of numerical calculations being done today are just
beginning to provide us with a set of tools that we need to understand
how the geodynamo works," says Bloxham. "There is just an enormous
amount of work that we need to do. But I think it's a very exciting
time."

_[2]References_ space _[3]Sources_

RedTriRule

[4]Table of Contents -- October 19, 1996

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References

1. http://www.sciencenews.org/sn_arch/7_20_96/fob1.htm
2. http://www.sciencenews.org/sn_arch/10_19_96/ref1.htm
3. http://www.sciencenews.org/sn_arch/10_19_96/src1.htm
4. http://www.sciencenews.org/sn_arch/10_19_96/content.htm
5. http://www.sciencenews.org/
6. http://www.sciencenews.org/index.htm#features
7. https://www.kable.com/pub/scnw/subServices.asp
8. http://www.sciencenews.org/sn_forms/sn_ctact.htm
9. http://www.sciencenews.org/AT-scinewsquery.html
10. http://www.sciencenews.org/
11. http://www.sciencenews.org/sn_wekly/sciserv.htm