As
the ever-increasing power of computer chips brings
us closer and closer to the limits of silicon technology,
many researchers are betting that the future will
belong to "spintronics": a nanoscale technology in
which information is carried not by the electron's
charge, as it is in conventional microchips, but
by the electron's intrinsic spin.
If a reliable way can be found to control and manipulate
the spins, these researchers argue, spintronic devices
could offer higher data processing speeds, lower
electric consumption, and many other advantages over
conventional chips--including, perhaps, the ability
to carry out radically new quantum computations.
Now, University of Notre Dame physicist Boldizsar
Janko and his colleagues believe they have found
such a control technique. Their work, funded by the
National Science Foundation through a Nanoscale Interdisciplinary
Research Team grant, was published in the March 5,
2005, edition of the journal Nature .
The idea is to create the device as a series of
layers, each only a few dozen nanometers thick. At
the base is a layer of diluted magnetic semiconductor,
a type of material Janko and his group have been
studying intensively. When gallium arsenide is doped
with manganese atoms, for example, each manganese
atom contributes an extra electron, and thus an extra
electron spin; the result is a semiconductor material
that can be magnetized in much the same way as iron.
Then an insulator material is layered over the base,
followed by a layer of superconducting material.
Next, a magnetic field is applied perpendicular
to the top surface (see animation above). Thanks
to the basic physics of superconductors, the field
can make it through only by pinching itself down
into an array of nanoscale flux tubes. That
super concentrates the field inside each tube, so
that it creates a spot of high-intensity magnetism
on the semiconductor layer below, which, in turn,
creates a patch of closely aligned electron spins.
The resulting spin patches, one for each flux tube,
are then available for encoding information.
The effect resembles what happens when you sprinkle
iron filings on a piece of paper, and then hold a
bar magnet underneath, says Janko: the presence of
the magnet (the flux tube) makes the iron filings
(the spins) stand at attention. Furthermore, he says,
just as you can manipulate the filings by moving
the magnet underneath the paper, you can manipulate
the spins in this system by moving the flux tubes.
For example, an electric current flowing through
the superconductor will cause a given flux tube to
move to one side (with the patch of spins underneath
moving along with it), while a current flowing in
the reverse direction will move it back to the other
side (see animation at right).
Although Janko and his colleagues have tested their
approach so far only through computer simulations,
experiments are now underway to demonstrate the technique
in the laboratory.
-NSF-
Media Contacts
William G. Gilroy, University of Notre Dame (574) 631-7367 gilroy.6@nd.edu
M. Mitchell Waldrop, NSF (703) 292-7752 mwaldrop@nsf.gov
Program Contacts
LaVerne D. Hess, NSF (703) 292-4937 lhess@nsf.gov
Principal Investigators
Boldizsar Janko, University of Notre Dame (574) 631 8049 bjanko@nd.edu
Related Websites
Boldizsar Janko's Research Page: http://www.nd.edu/~bjanko/
University of Notre Dame press release: http://newsinfo.nd.edu/content.cfm?topicid=11102
Spintronics article in Scientific American: http://www.sciam.com/article.cfm?articleID=0007A735-759A-1CDD-B4A8809EC588EEDF
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