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SAN
JOSE, CA -- (MARKET WIRE) -- 09/09/2004 -- IBM scientists
have measured a fundamental magnetic property of a
single atom -- the energy required to flip its magnetic
orientation. This is the first result by a promising
new technique they developed to study the properties
of nanometer-scale magnetic structures that are expected
to revolutionize future information technologies.
From spintronics to quantum
computing, a large number of dramatically new ideas
for electronic, computing and data storage devices
are emerging to exploit the remarkable properties
resulting from the magnetic orientations of electrons
and atoms.
"To engineer the anticipated
nanoscale features of these new types of circuits,
we will need fundamental knowledge of the magnetic
properties of small numbers of atoms in various environments,"
said Andreas Heinrich, research staff member at IBM's
Almaden Research Center in San Jose, California. "Our
new technique provides this information in much more
detail and precision than had been possible before."
Spintronics is an emerging
class of new electronic circuits that exploit the
magnetic orientation of electrons and atoms -- a quantum
property called "spin." An electron's spin
has two possible conditions, either "up"
or "down." Aligning spins in a material
creates magnetism. Most materials are non-magnetic
because they have equal numbers of up and down electron
spins, which cancel each other. But materials such
as iron, or cobalt have an unequal numbers of up and
down electron spins and are magnetic. In their new
result, the IBM researchers measured the energy required
to flip the spin of a single manganese atom from "up"
to "down."
This result is published in
a paper by Heinrich and colleagues Jay A. Gupta, Christopher
P. Lutz and Donald M. Eigler that appears in the September
9 issue of Science Express, the web edition of the
scientific journal Science, published by the American
Association for the Advancement of Science. (Gupta
is now an assistant professor at Ohio State University.)
Technical details
The new technique is a magnetic
version of "inelastic electron tunneling spectroscopy"
that the IBM scientists call "single-atom spin-flip
spectroscopy." To use it, the scientists first
place a magnetic atom on a surface and use a strong
magnetic field to orient its spin. Next, they position
a non-magnetic tip of a scanning tunneling microscope
(STM) above the atom being studied. By applying a
voltage to the tip, electrons are made to flow, or
"tunnel," from the tip to the magnetic atom.
Most of the time, the electrons
pass right through the atom. However, if the voltage
is great enough, some electrons can transfer energy
to the atom, causing a spin flip and the flow of electrons
to increase. By measuring the voltage at which the
electron flow begins to increase, the scientists can
determine the energy required to flip the spin.
The experiments are conducted
within a vacuum and at very low temperature -- less
than one degree Kelvin -- to achieve enough resolution
to measure the very small energy required to flip
the single spin of a lone manganese atom. They found
the energy, which varies somewhat with the strength
of the orienting magnetic field, to be about 0.0005
electron-volts -- some 10,000 times less than the
energy of a single molecular hydrogen bond.
IBM's technique is so sensitive
that the scientist learned that it takes 6 percent
more energy to flip the spin of atoms positioned near
the edge of an insulating patch on the surface than
for atoms in the middle of the patch. Such detail
will be valuable in understanding and engineering
the properties of future nanoscale spintronic devices.
Upcoming experiments will explore
how magnetic properties change when atoms are brought
together into small groups and in different geometries.
Background
This announcement is the latest
in a series of achievements in nanoscale science by
IBM Fellow Don Eigler and colleagues. Over the past
15 years, Eigler has led a group of young scientists
who have pioneered the use of STM atom manipulation
in wide-ranging experiments aimed at building and
understanding of the properties of atomic-scale structures
and exploring their potential for use in information
technologies such as digital logic and data storage.
The group's results include:
-- Positioning individual atoms
on surfaces,
-- Inventing an electrical switch with a single atom
as the active
element,
-- Building molecules one atom at a time,
-- Discovering that magnetic impurity atoms alter
the electronic
structure of superconductors over a surprisingly short
range,
-- Measuring for the first time how electrical conductance
through single-
and double-atom wires varies with chemical element,
-- Demonstrating the ability to image electron density
waves on metal
surfaces,
-- Inventing a new kind of electron trap called a
"quantum corral,"
-- Discovering the "quantum mirage" effect,
in which an electron's
quantum wave pattern is used to project information,
and
-- Demonstrating a complete functional computational
circuit based on the
"molecule cascade" motion of individual
molecules that is 260,000 times
smaller than that which could be made by the best
contemporary chip-making
methods.
This is also the third significant electron-spin research
announcement from IBM Almaden in recent months. The
earlier news was:
-- On April 26, IBM and Stanford University announced
the creation of
SpinAps, the IBM-Stanford Spintronic Science and Applications
Center, aimed
at creating new materials and devices with entirely
new capabilities --
such as reconfigurable logic devices, room-temperature
superconductors and
quantum computers -- that would create dramatically
new computational
paradigms.
-- In the July 15 issue of Nature, IBM Almaden scientists
described a
breakthrough in nanoscale magnetic resonance imaging:
using magnetic
resonance force microscopy to directly detect the
faint signal from a
single electron spin buried inside a solid sample.
For more information, contact:
Mike Ross
IBM Research
Almaden Research Center (San Jose, Calif.)
408-927-1283
mikeross@almaden.ibm.com
SOURCE: IBM
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