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The Sensible Superconductor
Some 18 months after its
discovery, magnesium diboride is on the road to
producing real-world applications
By Saswato R. Das, Contributing
Editor
Cheap to make, simple to cool, easy to shape into
wires, magnesium diboride could throw the field of
superconducting applications wide open. "It could
replace niobium-titanium, a conventional low-temperature
superconductor, in future MRI magnets," says visionary
Paul Grant, science fellow at the Electric Power
Research Institute (Palo Alto, Calif.). "It has to be
given serious attention."
Besides magnetic resonance imaging (MRI),
practical uses of the zero-resistance material in
transformers and fault current limiters seem not too
much to hope for.  Much further off, perhaps, could
be networks of superconducting power lines cooled by
liquid hydrogen, as proposed by Grant.
Until the magnesium diboride revelation,
engineers trying to apply superconductivity to the real
world had to grapple with distinctly un-ideal materials.
Low-temperature (metallic) superconductors, while not
too costly and with excellent mechanical properties,
require cooling down nearly to zero—4.2 K—a pricey
proposition. High-temperature (ceramic) superconductors
can be cooled at far less expense to a less chilly 77 K,
but their manufacturing process requires a great deal of
silver, a costly material.
Magnesium diboride falls between the two types on
the temperature scale. With a superconducting transition
temperature of 39 K, it can be conveniently cooled with
commercial cryocoolers or liquid hydrogen (boiling
point: 20.2 K).
A
powder that can be found in any well-stocked chemistry
laboratory, it had never been tested for
superconductivity until very recently. The five Japanese
researchers who did so announced their discovery in
January 2001 at a small conference in the Japanese city
of Sendai. The news spread among superconductor
cognoscenti like wild fire. Lights burned late into the
night in laboratories worldwide as scientists worked
overtime studying the inexpensive metallic compound's
properties with a view to harnessing its surprising
potential.
Within two weeks, Paul C. Canfield of Iowa State
University (Ames) and his physics/astronomy department
collaborators had made 3-cm-long wires out of the
compound by passing magnesium vapors over boron fibers.
"This material is just full of good news," he
said.
Two
months after the initial announcement, the American
Physical Society held its annual meeting in Seattle,
Wash., and arranged a special evening session of
magnesium diboride papers. The large hotel banquet hall
chosen for the event was jammed with physicists; the
session, which began after dinner, included dozens of
oral presentations and went on until 1 a.m.
The
attendees were fascinated by the wealth of data
indicating the compound was a conventional
(low-temperature metallic) superconductor. This augured
well for the future. Such a material can be explained by
the Bardeen-Cooper-Schrieffer (BCS) theory of
superconductivity, which says that the interactions
between the electrons in a superconductor are governed
by the thermal vibrations of atoms in the crystal
structure of the material. So the behavior of magnesium
diboride would be easy to understand. (The physical
mechanism responsible for superconductors of the
so-called high-temperature type is not yet clearly
understood.)
"It's rare that we get so excited," said Robert
J. Cava of Princeton University, an expert on
superconductivity and an attendee at the
conference.
But
initial data also showed researchers that they had some
work to do. In order for the material to be truly
useful, its current-carrying capability and magnetic
field tolerance would have to be improved and a
commercially viable and economical method of
manufacturing wires would have to be developed. Today,
little more than a year later, the news is very
encouraging.
Economical
ingredients
The materials
that go into making magnesium diboride, magnesium and
boron, are both dirt-cheap. EPRI's Grant believes that
magnesium diboride cable may eventually be comparable in
price to copper cable. When first discovered to be a
superconductor, a kilogram of high-purity magnesium
diboride cost about US $750.
But
with larger demand, the cost could drop dramatically.
Grant estimates that it could cost about $10/kg to
chemically reduce raw boron pentahydrate to metallic
boron. To react boron with magnesium to produce
magnesium diboride for wires would probably cost another
$10, he says. That adds up to $20/kg for the
material.
These numbers are "wet-fingers-in-the-wind
estimates and could wind up substantially in error,"
says the man from EPRI. "But let's say they represent a
lower limit. As an upper limit, commercially prepared
magnesium diboride should drop to $300 per kilogram with
volume demand."
In
the power transmission industry, the cost-to-performance
ratio is measured in cost per kiloampere-meter. The cost
of making magnesium diboride wires will be around
$1/kA-m, Grant says. In contrast, high-temperature
superconducting ceramic wires sell for about $200/kA-m
today. (The price is expected to fall to about $50/kA-m
in two or three years). Made of bismuth, strontium,
calcium, and copper oxide, often called BSCCO, they are
sheathed expensively in silver for structural,
metallurgical, and electrical reasons.
Length no problem
Two companies
are working to commercialize magnesium diboride wires
for applications like coils and cable: Hyper Tech
Research in the United States (Troy, Ohio) [see photo]
and Diboride
Conductors in the United Kingdom (Cambridge). Hyper Tech
has made wires as long as 100 meters, but so far has
electrically tested only shorter segments.
The
Hyper Tech method of wire-pulling is a modified
powder-in-tube approach, explains Mike Tomsic, the
company's president. In fact, it is the process used to
make most superconducting wires that start out as
powders [see figure ]
, except that in the
Hyper Tech approach, the iron tube is being formed
continually. A U-shaped iron tube is filled with the
powder and then closed down to form a round wire about 6
mm across, which in turn is drawn down to about a
quarter of its starting thickness [see photo].
To form
multifilament wires, several filaments are stacked into
a tube, which is drawn down to a width of about 1.4
mm.
Progress in making magnesium diboride wire and
tape has been rapid. As early as May 2001, Sungho Jin
and colleagues at Agere Systems (Allentown, Pa.), a
spinoff of Lucent Technologies, had made magnesium
diboride tape in lengths of almost 1 meter with very
little fuss. They took iron tubes with outside diameters
of about 6 mm, filled them with magnesium diboride
powder, then flattened and stretched the tubes until
they became ribbons about 5 mm wide and 0.5 mm thick.
Lastly, they baked the ribbons at a temperature of 900
°C, which fused the powder into a solid.
"In
principle, using this process, you could make the wires
as long as you like," said Jin. He pointed out, too,
that inexpensive iron could be used for the magnesium
diboride sheath as opposed to the silver used with
high-temperature superconducting ceramics.
Cool comfort
A
distinct advantage of the high-temperature ceramic
superconductors is that they can be cooled by liquid
nitrogen, which is very cheap in itself and, with its
77-K transition temperature, also cheap to keep cool.
Conversely, wires made of conventional superconductors
like niobium-titanium need to be cooled, at great
expense, to liquid helium temperatures. Magnesium
diboride, which falls in between, needs to be chilled to
20-30 K for it to be useful. While this is colder than
liquid nitrogen, it is within the range of a standard
commercial cryocooler, and the cost is not that high.
"There's an entire world of economic difference between
liquid helium temperatures and the temperature at which
this material operates," says Grant.
For
applications such as transformers for electric utility
grids, magnesium diboride seems a good choice, he
continues. In fact, they may be the entry application
that the material needs to gain a foothold in the
marketplace. According to his estimates, magnesium
diboride transformers will be more economically
attractive not only than those based on high-temperature
superconductors but even than those using copper wire.
According to Grant, the ownership costs
associated with a magnesium diboride transformer,
operating at 25 K, would be about $59/kA-m, most of it
due to cooling costs. For a copper transformer,
operating at 300 K (room temperature), this figure is
around $65/kA-m, mostly due to resistive losses. For a
high-temperature ceramic superconductor, operating at 77
K, this figure is between $80 and $180/kA-m, most of it
coming from the cost of the wire.
The
wires may also be used to improve the performance of
electric motors and generators, because superconducting
coils can carry much more current than copper. Thin
superconducting films could serve as electronic
components and sensitive magnetic sensors. Other
potential roles would be in superconducting magnets and
wireless base stations.
On
15-16 November 2001, a conference on the practical
applications of superconductors was organized in Boston
by the Knowledge Foundation (Brookline, Mass.). To
attendee Deborah Van Vechten, magnesium diboride looked
"very positive" for wireless receivers with ultrahigh
signal sensitivity and transmitters with ultralow phase
noise. Van Vechten is the program officer for
superconductivity for the U.S. Office of Naval
Research.
Also
present was Jun Akimitsu, the leader of the Japanese
team that announced the superconducting behavior of
magnesium diboride. He told IEEE Spectrum that the
Japanese government has started funding a big effort to
find industrial applications for the material. "This
material has many features—it's very light, cheap, and
easily made," he said. "I believe it has a big potential
for applications."
Few
disagree with Akimitsu.
"If
magnesium diboride had been discovered in the 1960s and
1970s," said Cava, the Princeton expert who wrote a
commentary on the importance of the discovery, then "the
whole culture of superconductivity research would have
been different."
Nothing's perfect
With the announcement of magnesium diboride's
unsuspected talent, superconductivity has, almost
overnight, shot into prominence again. Yet, compared
with other superconductors, magnesium diboride did have
a few shortcomings to overcome.
The
material's inability to carry much current was one that
surfaced early. In May 2001, Jin and his colleagues at
Agere reported that their wires could carry 35 000
A/cm2. (Real-life superconductor applications
require a larger value, at least 80 000
A/cm2.) However, that figure has moved
sharply upward, and is currently at around 200 000
A/cm2 for a magnetic field of 1 tesla,
typical of transformers and motors.
More
worrisome is the material's inability to stand up to
very strong magnetic fields. Early data showed that its
superconductivity vanished in fields greater than 2 T,
which produces magnetic vortices inside the alloy [see
figure ].
These vortices
move under the Lorenz force created by the current, and
their motion dissipates energy, which shows up as
electrical resistance.
The
solution turns out to lie in making the material less
structurally perfect. A team led by David Caplin at
London's Imperial College found that structural defects
induced in the alloy pin the vortices and keep them from
moving. The team bombarded samples of magnesium diboride
with protons and found the resulting defects greatly
enhanced the material's ability to shepherd current
through a magnetic field. While proton bombardment is
impractical for large-scale manufacture of wire, the
research suggests that chemical doping may work just as
well.
"We've shown that modest disorder, at the level
of about 1 percent, can generate a material whose
performance is technologically attractive," and
attainable in an economically viable way, either by
chemical doping or mechanical processing, Caplin
explained.
As
it happens, chemical doping is now yielding the
predicted improvement. A technique that adds oxygen to
thin films of the superconductor is being pioneered at
the University of Wisconsin at Madison by Chang-Beom
Eom, professor of materials science and engineering, and
colleagues.
"We
believe that oxygen goes into the lattice and replaces
some of the boron atoms," Eom told Spectrum. He says it
is an alloying process that improves both the
current-carrying capacity and magnetic field tolerance.
More than one mechanism is at work, it appears. Adding
oxygen also creates minute particles of magnesium oxide
that aggravate the disorder.
But
can the techniques Eom uses to improve the
superconducting properties of magnesium diboride films
also be used for wires? Eom is unsure. And Hyper Tech's
Tomsic cautions that although there has been a proof of
principle that there are ways to improve vortex pinning,
doing it in a wire uniformly is a big challenge.
If
these magnetic issues are resolved without harm to the
economics of production, magnesium diboride wires could
prove of use in medical diagnostic machines that use
powerful magnets for magnetic resonance imaging.
A challenger in the
wings
Given the
heady excitement of the past year, some physicists who
have worked in superconductivity dream of the day when
magnesium diboride wires are in common use. But even if
the material proves its mettle against BSCCO, it may be
on a collision course with a so-called second-generation
high-temperature superconductor, a compound of yttrium,
barium, copper, and oxygen, which is in the early stages
of development.
Like
BSCCO, YBCO is superconducting above liquid nitrogen
temperature. But it is cheaper to manufacture and has
better magnetic field characteristics. To make matters
more interesting, magnesium diboride and YBCO are on the
same development time line. Hyper Tech's Tomsic expects
to be selling magnesium diboride wire commercially by
2004 or 2005 at $1-2/kA-m. On the YBCO side, Philip J.
Pellegrino, president of IGC-SuperPower (Schenectady,
N.Y.) told Spectrum that he plans to sell the
second-generation superconductor at about $10/kA-m in
the second half of this decade.
Linda Geppert, Editor
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