Molecular transistor
Researchers have built
a simple and transparent transistor using a single molecule and some atoms. The
breakthrough could be fundamental for future gadgets
An international team of physi cists
has used a scanning tun neling microscope to create a minute transistor
consisting of a single molecule and a small number of atoms. The observed
transistor action is markedly different from the conventionally expected
behaviour and could be important for future device technologies as well as for
fundamental studies of electron transport in molecular nanostructures. The
physicists represent the Paul-Drude-Institut fur Festkorperelektronik (PDI) and
the Freie Universitat Berlin (FUB), Germany, the NTT Basic Research Laboratories
(NTT-BRL), Japan, and the US Naval Research Laboratory (NRL).Their complete
findings appear in the journal Nature Physics.
Transistors have a channel region
between two external contacts and an electrical gate electrode to modulate the
current flow through the channel.In atomic-scale transistors, this current is
extremely sensitive to single electrons hopping via discrete energy levels. In
earlier studies, researchers have examined single-electron transport in
molecular transistors using top-down approaches, such as lithography and break
junctions. But atomically precise control of the gate which is crucial to
transistor action at the smallest size scales is not possible with these
approaches.
The team used a highly stable
scanning tunneling microscope (STM) to create a transistor consisting of a
single organic molecule and positively charged metal atoms, (phthalocyanine
molecule with twelve indium atoms), positioning them with the STM tip on the
surface of an indium arsenide (InAs) crystal. Kiyoshi Kanisawa, a physicist at
NTT-BRL, used the growth technique of molecular beam epitaxy to prepare this
surface. Subsequently, the STM ap proach allowed the researchers to assemble
electrical gates from the +1 charged atoms with atomic precision and then to place
the molecule at various desired positions close to the gates.
Stefan Fölsch, a physicist at the
PDI who led the team, explained that “the molecule is only weakly bound to the
InAs template. So, when we bring the STM tip very close to the molecule and apply
a bias voltage to the tip-sample junction, single electrons can tunnel between
template and tip by hopping via nearly unperturbed molecular orbitals, similar
to the working principle of a quantum dot gated by an external electrode. In
our case, the charged atoms nearby provide the electrostatic gate potential
that regulates the electron flow and the charge state of the molecule.“
But there is a substantial
difference between a conventional semiconductor quantum dot comprising
typically hundreds or thousands of atoms and the present case of a
surface-bound molecule.
Steven Erwin, a physicist at NRL and
expert in density-functional theory, pointed out that, “the molecule adopts
different rotational orientations, depending on its charge state. We predicted
this based on first-principles calculations and confirmed it by imaging the
molecule with the STM.“
This coupling between charge and
orientation has a dramatic effect on the electron flow across the molecule,
manifested by a large conductance gap at low bias voltages.
Piet Brouwer, a physicist at FUB and
expert in quantum transport theory, said, “This intriguing behaviour goes
beyond the established picture of charge transport through a gated quantum dot.
Instead, we developed a generic model that accounts for the coupled electronic
and orientational dynamics of the molecule.“ This simple and physically
transparent model entirely reproduces the experimentally observed
single-molecule transistor characteristics.
MM17JUL15
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