The electrons
of a perfect metallic surface move like free waves
in a plane. Nevertheless, if atomic barriers are inserted,
this may restrict their movement in one dimension,
forming stationary waves such as those on the water
surface in a bucket.
The
stationary or free behaviour of electron waves is,
nevertheless, still something very intriguing, given
that the barriers of atoms are very close to each
other, there is no confinement, and that the electron
recovers its free movement, exactly as was discovered
some years ago by the Nanophysics Laboratory research
team led by Enrique Ortega at the Donostia-San Sebastian
campus of the University of the Basque Country.
The
prestigious magazine Physical Review Letters, the
most important in the world in the field of Physics,
has just published the results of new research this
team has been undertaking since 1999 on the wave properties
of electrons: the critical size of the step is 2 nanometres,
i.e., if the distance of the barriers is superior
to 2 nanometres, the electrons form stationary waves;
if it is inferior, the waves are free.
More
specifically, Enrique Ortega has formed a new nanostructure,
i.e. a typical nanometre-sized structure (a nanometre
being a thousand millionth or a billionth of a metre)
by depositing small quantities of silver on a copper
surface. The system arranges itself by forming a network
of nanostrips of silver and copper. The copper strips
show atomic steps with a step width that depends on
the amount of silver deposited. On varying the width,
one can observe in detail the transformation of the
stationary waves confined between the steps of atomic
height in waves of electrons that move freely.
In
this way the critical size of the step of 2 nanometres
has been discovered: less than this width free waves
exist and widths greater than this critical figure
are confined. “The detailed study of this transition
will be fundamental in the future when establishing
the wave properties of electrons in metallic nanostructures",
stated Enrique Ortega.
According
to Doctor Ortega, the most difficult part of the investigation
was constructing the system by which the measurement
was to be carried out. These kinds of trials have
to be undertaken in ultra high vacuum systems, where
not even the smallest particle can be present, as
the least amount of contamination will destroy the
system. They are also systems difficult to extract
information from. Moreover, it is necessary to create
a structure limited to a width of 4 or 5 atoms, controlling
all the parameters at the same time, demanding a complex
prior process.
This
is the sixth time that Dr Ortega, leader of the only
experimental physics group working on nanostructures
in Euskadi, has published an article in Physical Review
Lettersz. Regarding the applications for the discovery,
the researcher points out that “although, in the field
of nanoscience, one always has to go through a number
of phases, we cannot discard its utility, certainly
in the field of what will be the electronics of the
future - nanoelectronics”.
Reference
URL
http://www.basqueresearch.com
For
further information, please contact:
Garazi Andonegi
Elhuyar Fundazioa
garazi@elhuyar.com
+34 943 363040
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