Stanford researchers create exotic electrons that may lead to new materials, devices
The handcrafted, honeycomb-shaped structures were inspired by graphene,
a pure form of carbon widely heralded for its potential in future electronics.
By Mike Ross
Precisely positioned carbon monoxide molecules (black) guide electrons (yellow-orange) into a nearly perfect
honeycomb pattern called molecular graphene.
March 14, 2012
Researchers from Stanford University and the U.S. Department of Energy's
SLAC National Accelerator Laboratory have created the
first-ever system of "designer electrons" – exotic variants of ordinary electrons with tunable properties that may ultimately lead to
new types of materials and devices.
"The behavior of electrons in materials is at the heart of essentially all of today's technologies," said
Hari Manoharan, associate
professor of physics at Stanford and a member of SLAC's
Stanford Institute for Materials and Energy Science,
who led the research.
"We're now able to tune the fundamental properties of electrons so they behave in ways rarely seen in ordinary materials."
Their first examples, reported Wednesday in
Nature, were handcrafted, honeycomb-shaped structures
inspired by graphene, a pure form
of carbon that has been widely heralded for its potential in future electronics.
Initially, the electrons in this structure had graphene-like properties. Unlike ordinary electrons, for example, they had no mass and
traveled as if they were moving at the speed of light in a vacuum. But researchers were then able to tune these electrons in ways that
are difficult to do in real graphene.
To make the structure, which Manoharan calls molecular graphene, the scientists use a scanning tunneling microscope to place individual
carbon monoxide molecules on a perfectly smooth copper surface. The carbon monoxide repels the free-flowing electrons on the copper
surface and forces them into a honeycomb pattern, where they behave like graphene electrons.
To tune the electrons' properties, the researchers repositioned the carbon monoxide molecules on the surface; this changed the
symmetry of the electron flow. In some configurations, electrons acted as if they had been exposed to a magnetic or electric field.
In others, researchers were able to finely tune the density of electrons on the surface by introducing defects or impurities.
By writing complex patterns that mimicked changes in carbon-carbon bond lengths and strengths in graphene, the researchers were
able to restore the electrons' mass in small, selected areas.
"One of the wildest things we did was to make the electrons think they are in a huge magnetic field when, in fact, no real field
had been applied," Manoharan said.
Guided by the theory developed by co-author Francisco Guinea of Spain, the Stanford team calculated the positions where carbon atoms
in graphene should be to make its electrons believe they were being exposed to magnetic fields ranging from zero to 60 tesla, more
than 30 percent higher than
the strongest continuous magnetic field ever achieved on Earth.
The researchers then moved carbon monoxide
molecules to steer the electrons into precisely those positions, and the electrons responded by behaving exactly as predicted – as if
they had been exposed to a real field.
"Our new approach is a powerful new test bed for physics," Manoharan said. "Molecular graphene is just the first in a series of
possible designer structures. We expect that our research will ultimately identify new nanoscale materials with useful electronic
properties."
Additional authors included Kenjiro K. Gomes, Warren Mar and Wonhee Ko of the Stanford Institute for Materials and Energy Science.
Guinea is a researcher at the Madrid Materials Science Institute. The research was supported by the U.S. Department of Energy's Office
of Basic Energy Sciences, the National Science Foundation and the Spanish Ministry of Science & Innovation.
Mike Ross is a science writer in the Office of Communications at the SLAC National Accelerator Laboratory.
Hari Manoharan and his team have created an artificial form of graphene on a copper crystal,
by moving individual molecules with a high-powered scanning tunneling microscope.
Back to Magazine