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Penn State Researchers Collaborate on Findings That
Make Way
According to California Institute of Technology physicist Michael
L. Roukes, who reviewed the paper for the journal's "News and
Views" section and discussed the demonstration of spin transfer across
semiconductor interfaces, "This achievement is an important milestone
in the race to build futuristic devices that exploit the true quantum
nature of electrons." A complete release follows. Contact: Jacquelyn Savani (UCSB) Spin Moves With Unexpected Ease From One Semiconductor
to Another Successful Demonstration of Spin-Transfer Makes Way
for Santa Barbara, California -- Four researchers
at the University of California at Santa Barbara (UCSB) and at Penn State
University in University Park, Pa., report in the June 14 issue of Nature
experiments that show high-efficiency spin transfer through interfaces
between two different semiconductor materials. The paper "Persistent
Sourcing of Coherent Spins for Multifunctional Spintronics" also
announces the discovery of a new "persistent" mode of spin currents
that makes semiconductor reservoirs act, in effect, as "spin batteries." Physicist David Awschalom heads the research team that conducted
the experiments reported in Nature. He is director of the UCSB
Center for Spintronics and Quantum Computation, a key component of the
new California NanoSystems Institute [CNSI] located jointly at UCSB and
UCLA. The experiments are the result of long-standing collaboration between
Awschalom and Nitin Samarth, a materials physicist at Penn State
University. This likely landmark paper is the subject of the lead "News and
Views" article in the June 14 Nature. In his review of the
paper, Caltech physicist Michael L. Roukes, said of the demonstration
of spin transfer across semiconductor interfaces, "This achievement
is an important milestone in the race to build futuristic devices that
exploit the true quantum nature of electrons." Electrons have both charge and spin. Electronic devices such as transistors
operate, as Roukes describes, "by internally shuttling small packets
of electronic charge." All semiconductor technology is based on charge.
But electrons also spin, or rotate. The results reported in Nature
answer affirmatively the key question of whether a whole new spin-based
technology is feasible. Hold a pencil upright and rotate it in the same direction by turning
it alternately between the thumb and index finger of one hand and the
other. While rotating it, turn it upside down. Note that when inverted,
the direction of rotation changes from, say, clockwise to counterclockwise. That pencil is analogous to the axis of rotation of an electron. The
two orientations of the axis of rotation--up or down--are the conventional
or classical ways physicists describe spin. That description is sufficient
for understanding the results in the Nature paper (though spin
as a quantum mechanical property is understood not merely as up or down,
but the superposition of all orientations of the axis of rotation). Awschalom said, "The results of these experiments were as much a
surprise to us as to anyone. Spin appears to be remarkably robust and
moves relatively easily between semiconductors. Previously, theories of
electron transport from one material to another suggested that the spin
would lose its orientation or scatter from impurities or structural effects.
These experiments point out that this is not the case." In these measurements the spins of each electron all point in the same
direction or are aligned. The question was whether a cloud or bundle of
electrons all spinning the same way would retain that same spinning when
the cloud is moved to an adjacent semiconducting material. The spins in
fact stayed aligned. What astonished Awschalom, his graduate student
Irina Malajovich (first author on the Nature paper), and her
co-workers at Penn State is that the spins not only stayed aligned but
did so as the temperature of the materials was raised, in some cases,
to room temperature. Certain semiconductors were found to work as spin reservoirs because
spins survive there for long times. In analogy with conventional charge-based
electronics, this work shows that electrons can be withdrawn from such
reservoirs with their spin intact, using electric fields. Spin reservoirs
are thereby "sourcing" a spin current. A year ago Awschalom took his preliminary results to UCSB Engineering
Professor Herb Kroemer, who won the 2000 Nobel Prize in Physics
for envisioning the heterojunction, one example of which is a sandwich
using n- and p-type semiconductors. The charge carriers in n-type semiconductors
are electrons, and the charge is negative: in p-type semiconductors the
charge carriers are holes, and the charge is positive. Kroemer saw that
putting two materials, one n-type and the other p-type together, would
create an internal electric field that would promote the flow of spins
across the interface. Malajovich's initial experiments showed spin transfer between two n-type
semiconductors. Kroemer suggested trying to move spin from a p- to an
n-type semiconductor. "To my surprise," said Awschalom, "it
worked very well. Instead of applying an external electric field to move
the electrons from one material to another, we were able to use the internal
field created by assembling two different kinds of semiconducting layers.
It not only worked," said Awschalom, "but the effect was even
stronger. "The basis of the transistor is the p-n junction," said Awschalom.
"The implication of these results is that there is no fundamental
reason one can't move forward and fabricate spin transistors. I hope that
some research team will demonstrate this in the near future. At present
transistors are the building blocks of electronics. It's exciting to think
about future technologies that exploit the electron spin and function
in a completely different manner. For example, imagine devices that could
combine photonics, electronics, and magnetics in a single structure." There is yet another discovery reported. Said Awschalom, "Unexpectedly,
if you keep pulling spin from one material to another, the spins in the
adjacent layer acquire the original spin frequency and lifetime of the
reservoir. Therefore the total transferred spin can have the properties
of either the reservoir or the adjacent layer, and an external electric
field 'gates' the transition between the two very different regimes. That
is the 'persistent sourcing' of the paper's title. The fact that this
behavior can be tuned with either electric or magnetic fields results
in a new multi-functional type of 'spintronics.' " In his "News and Views" article, Roukes notes that this "newly-identified,
persistent mode of spin transfer . . . makes the reservoir act, in effect,
as a spin 'battery.' " Asked what that is good for, Awschalom said, "New discoveries enable
new technologies. It's likely the most important applications are yet
to be realized." The Penn State University researchers, Samarth and his graduate student
Joseph Berry, used Molecular Beam Epitaxy (MBE) to fabricate the compound
semiconductor heterostructures for the physics experiments that were carried
out at Santa Barbara. The choice of structurally compatible semiconductors
with very different optical and electronic characteristics was particularly
crucial to designing an experiment whose results would be unambiguous. Samarth said, "One of the implications of this experiment is that
one can construct basic building blocks for spin electronics using well-understood,
conventional semiconductors. This collaboration also shows how integral
material science is to fundamental research, and is a first-rate demonstration
of how laboratories without walls can work. Getting these experiments
to work needed close collaboration between the graduate students. Though
not face to face, Irina and Joe worked smoothly together. And the results
are delightful!" DARPA (Defense Advanced Research Project Agency) funds the collaborative
research between UCSB and Penn State through two programs, SPINS and QUIST.
Awschalom went to Washington, D.C., to present his findings to the Defense
Science Board on June 8. [NOTE: Professor Awschalom can be reached at 805-893-2121, and Professor Samarth at 814-863-0136. For a high resolution version of the full graphic, which in part accompanied the Nature "News and Views" article, go to ftp://kk.engr.ucsb.edu/Press_Releases/David_Awschalom/ .]
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5
June 2001-- Researchers from the University of California at Santa
Barbara (UCSB) and Penn State report in the 14 June issue of Nature
experiments that show high-efficiency spin transfer through interfaces
between two different semiconductor materials. The paper also announces
the discovery of a new "persistent" mode of spin currents that
makes semiconductor reservoirs act, in effect, as "spin batteries."
The experiments are the result of a long-standing collaboration between
David Awschalom at UCSB and Nitin Samarth at Penn State.