Imagine a future in which plugs and external power sources no longer limit our electrical gadgets.
This possibility is one of the reasons for the current interest in building the capacity to store electrical energy directly into a wide range of products, such as a laptop whose casing serves as its battery, or an electric car powered by energy stored in its chassis, or a home where the dry wall and siding store the electricity that runs the lights and appliances.
“These devices demonstrate—for the first time as far as we can tell—that it is possible to create materials that can store and discharge significant amounts of electricity while they are subject to realistic static loads and dynamic forces, such as vibrations or impacts,” says Cary Pint, assistant professor of mechanical engineering at Vanderbilt University.
He and graduate student Andrew Westover have built small “wafer” devices in the Nanomaterials and Energy Devices Laboratory there. “Andrew has managed to make our dream of structural energy storage materials into a reality,” says Pint.
That is important because structural energy storage will change the way in which a wide variety of technologies are developed in the future.
“When you can integrate energy into the components used to build systems, it opens the door to a whole new world of technological possibilities. All of a sudden, the ability to design technologies at the basis of health, entertainment, travel, and social communication will not be limited by plugs and external power sources,” Pint says.
The new device that Pint and Westover have developed is a supercapacitor that stores electricity by assembling electrically charged ions on the surface of a porous material, instead of storing it in chemical reactions the way batteries do.
As a result, supercaps can charge and discharge in minutes, instead of hours, and operate for millions of cycles, instead of thousands of cycles like batteries.
In a paper appearing online in the journal Nano Letters, Pint and Westover report that their new structural supercapacitor operates flawlessly in storing and releasing electrical charge while subject to stresses or pressures up to 44 psi and vibrational accelerations over 80 g (significantly greater than those acting on turbine blades in a jet engine).
Furthermore, the mechanical robustness of the device doesn’t compromise its energy storage capability. “In an unpackaged, structurally integrated state our supercapacitor can store more energy and operate at higher voltages than a packaged, off-the-shelf commercial supercapacitor, even under intense dynamic and static forces,” Pint says.
One area where supercapacitors lag behind batteries is in electrical energy storage capability: Supercaps must be larger and heavier to store the same amount of energy as lithium-ion batteries. However, the difference is not as important when considering multifunctional energy storage systems.
“Battery performance metrics change when you’re putting energy storage into heavy materials that are already needed for structural integrity,” says Pint.
“Supercapacitors store ten times less energy than current lithium-ion batteries, but they can last a thousand times longer. That means they are better suited for structural applications. It doesn’t make sense to develop materials to build a home, car chassis, or aerospace vehicle if you have to replace them every few years because they go dead.”
Westover’s wafers consist of electrodes made from silicon that have been chemically treated so they have nanoscale pores on their inner surfaces and then coated with a protective ultrathin graphene-like layer of carbon. Sandwiched between the two electrodes is a polymer film that acts as a reservoir of charged ions, similar to the role of the electrolyte paste in a battery.
When the electrodes are pressed together, the polymer oozes into the tiny pores in much the same way that melted cheese soaks into the nooks and crannies of the bread in a panini. When the polymer cools and solidifies, it forms an extremely strong mechanical bond.
“The biggest problem with designing load-bearing supercaps is preventing them from delaminating,” says Westover. “Combining nanoporous material with the polymer electrolyte bonds the layers together tighter than superglue.”
The use of silicon in structural supercapacitors is best suited for consumer electronics and solar cells, but Pint and Westover are confident that the rules that govern the load-bearing character of their design will carry over to other materials, such as carbon nanotubes and lightweight porous metals like aluminum.
The intensity of interest in “multifunctional” devices of this sort is clear: The US Department of Energy’s Advanced Research Project Agency for Energy is investing $8.7 million in research projects that focus specifically on incorporating energy storage into structural materials.
There have also been recent press reports of several major efforts to develop multifunctional materials or structural batteries for use in electric vehicles and for military applications.
However, Pint points out that there have not been any reports in the technical literature of tests performed on structural energy storage materials that show how they function under realistic mechanical loads.
The National Science Foundation supported the work. Materials fabrication took place in part at the Center for Nanophase Materials Sciences at Oak Ridge National Laboratory, which is supported by the Office of Basic Energy Sciences of the US Department of Energy.
Source: Vanderbilt University