‘Invisibility’ could be a key to better electronics
MIT team applies technology developed for visual ‘cloaking’ to enable more efficient transfer of electrons.
Diagram shows the 'probability flux' of electrons, a representation of the paths of electrons as they pass through an
'invisible' nanoparticle. While the paths are bent as they enter the particle, they are subsequently bent back so that
they re-emerge from the other side on the same trajectory they started with — just as if the particle wasn't there.
Image courtesy Bolin Liao et al.
October 12, 2012
David L. Chandler, MIT News Office
A new approach that allows objects to become “invisible” has now been applied to an entirely different area: letting particles
“hide” from passing electrons, which could lead to more efficient thermoelectric devices and new kinds of electronics.
The concept — developed by MIT graduate student Bolin Liao, former postdoc Mona Zebarjadi
(now an assistant professor at Rutgers University), research scientist Keivan Esfarjani, and mechanical engineering professor
Gang Chen — is
described in a paper
in the journal Physical Review Letters.
Normally, electrons travel through a material in a way that is similar to the motion of electromagnetic waves, including light;
their behavior can be described by wave equations. That led the MIT researchers to the idea of harnessing the cloaking mechanisms
developed to shield objects from view — but applying it to the movement of electrons, which is key to electronic and thermoelectric
Previous work on cloaking objects from view has relied on so-called metamaterials made of artificial materials with unusual
properties. The composite structures used for cloaking cause light beams to bend around an object and then meet on the other side,
resuming their original path — making the object appear invisible.
“We were inspired by this idea,” says Chen, the Carl Richard Soderberg Professor of Power Engineering at MIT, who decided to study
how it might apply to electrons instead of light. But in the new electron-cloaking material developed by Chen and his colleagues,
the process is slightly different.
The MIT researchers modeled nanoparticles with a core of one material and a shell of another. But in this case, rather than
bending around the object, the electrons do actually pass through the particles: Their paths are bent first one way, then back
again, so they return to the same trajectory they began with.
In computer simulations, the concept appears to work, Liao says. Now, the team will try to build actual devices to see whether
they perform as expected. “This was a first step, a theoretical proposal,” Liao says. “We want to carry on further research on
how to make some real devices out of this strategy.”
While the initial concept was developed using particles embedded in a normal semiconductor substrate, the MIT researchers would
like to see if the results can be replicated with other materials, such as two-dimensional sheets of graphene, which might offer
interesting additional properties.
The MIT researchers’ initial impetus was to optimize the materials used in thermoelectric devices, which produce an electrical
current from a temperature gradient. Such devices require a combination of characteristics that are hard to obtain: high electrical
conductivity (so the generated current can flow freely), but low thermal conductivity (to maintain a temperature gradient).
But the two types of conductivity tend to coexist, so few materials offer these contradictory characteristics. The team’s
simulations show this electron-cloaking material could meet these requirements unusually well.
The simulations used particles a few nanometers in size, matching the wavelength of flowing electrons and improving the flow
of electrons at particular energy levels by orders of magnitude compared to traditional doping strategies. This might lead to
more efficient filters or sensors, the researchers say. As the components on computer chips get smaller, Chen says,
“we have to come up with strategies to control electron transport,” and this might be one useful approach.
The concept could also lead to a new kind of switches for electronic devices, Chen says. The switch could operate by
toggling between transparent and opaque to electrons, thus turning a flow of them on and off. “We’re really just at the
beginning,” he says. “We’re not sure how far this is going to go yet, but there is some potential” for significant applications.
Xiang Zhang, a professor of mechanical engineering at the University of California at Berkeley who was not involved in
this research, says “this is very exciting work” that expands the concept of cloaking to the domain of electrons.
The authors, he says, “uncovered a very interesting approach that may be very useful to thermoelectric applications.”
This research was funded by the U.S. Department of Energy (DOE) through MIT’s Solid-State Solar-Thermal Energy Conversion center,
a DOE Energy Frontier Research Center.