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Delft University of Technology Discovers
How to Control Nanowires
Jorden van Dam, researcher at the Kavli
Institute of Nanoscience Delft, has succeeded in largely
controlling the transportation of electrons in semiconductor
nanowires. Van Dam moreover discovered how to observe
a divergent type of supercurrent in these wires. Nanowires
have superior electronic properties, which in time could
improve the quality of our electronics. On Tuesday,
June 13, Van Dam will receive his
PhD degree at Delft University of Technology based on
this research.
During his PhD research, Jorden van Dam focused on semiconductor
nanowires. These are extremely thin wires (1-100 nanometers
thick) made of, for example, the material indiumarsenide,
which has superior electronic properties. The integration
of these high quality nanowires with the now commonly
used silicium technology offers intriguing possibilities
for improving our electronics in future. According to
Van Dam, in recent years many possible applications
for semiconductor nanowires have emerged, such as in
lasers, transistors, LEDs, and bio-chemical sensors.
Philips is one of the companies conducting intensive
research into the possibilities for semiconductor nanowires
in specific applications.
Van Dam was able to make a so-called quantum dot in
a semiconductor nanowire (this is done at extremely
low temperatures). These quantum dots can be regarded
as artificial atoms and in the distant future will serve
as building blocks for super-fast quantum computers.
In a quantum dot, a number of electrons can be 'confined'.
The magnificence of Van Dam's research is the total
control he has managed to gain over the number of electrons
that can be confined in a quantum dot. He can control
this number by means of an externally introduced charge.
A crucial factor for the extreme degree of control that
Van Dam has achieved is the quality (for example the
purity) of the nanowires, which were supplied by Philips.
It is above all the quality of the material used (wires
and electrodes) that was greatly improved during Van
Dam's research.
The research also produced new physical observations.
In the improved nanowires, Van Dam achieved for the
first time the realization and observation of a (theoretically
already predicted) divergent type of supercurrent (a
supercurrent is the current that occurs in superconductivity).
In a quantum dot, the electrons normally pass through
one by one. In superconductivity, the passage of electrons
occurs in pairs. Van Dam, with the help of superconductor
electrodes, has now achieved a supercurrent in the quantum
dot, whereby the pairs of electrons pass through one
by one.
Van Dam has also – under specific conditions –
achieved a reversal in the direction of the supercurrent.
He is able to control this reversal by varying the number
of electrons confined in the quantum dot. With this,
the Delft University of Technology researcher has achieved
a largely controllable superconductor connection in
semiconductor nanowires.
Visit www.drc.tudelft.nl
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