Research Reveals Carbon Films Can Give Microchips Energy Storage Capability
February 19, 2016 | Drexel UniversityEstimated reading time: 3 minutes
After more than half a decade of speculation, fabrication, modeling and testing, an international team of researchers led by Drexel University’s Yury Gogotsi, PhD, and Patrice Simon, PhD, of Paul Sabatier University in Toulouse, France, have confirmed that their process for making carbon films and micro-supercapacitors will allow microchips and their power sources to become one and the same.
The discovery, which was reported in a recent edition of the journal Science, is the culmination of years of collaborative research by the team who initially created the carbide-derived carbon film material for microsupercapacitors and published the concept paper in Science in 2010. Since then, their goal has been to show that it’s possible to physically couple the processing center of an electronic device — the microchip — with its energy source.
“This has taken us quite some time, but we set a lofty goal of not just making an energy storage device as small as a microchip — but actually making an energy storage device that is part of the microchip and to do it in a way that is easily integrated into current silicon chip manufacturing processes,” said Simon, who led the research under the aegis of the French research network on electrochemical energy storage (RS2E), a spin-off of Le Centre National de la Recherche Scientifique (CNRS) and France’s Ministry of Research. “With this achievement, the future is now wide open for chip and personal electronics manufacturers.”
It confirms a belief that the group has held since the materials were first fabricated — that these films are versatile enough to be seamlessly integrated into the systems that power silicon-based microchips that run devices from your laptop to your smart watch.
The challenges that the group faced in the development of the material were questions about its compatibility, its mechanical stability and durability for use on flexible substrates. With these answered, it opens up a myriad of possibilities for carbon films to work their way into silicon chips — including building microscale batteries on a chip.
“The place where most people will eventually notice the impact of this development is in the size of their personal electronic devices, their smart phones, fitbits89 and watches,” said Gogotsi, Distinguished University and Trustee Chair Professor in the Department of Materials Science Engineering who directs the A.J. Drexel Nanomaterials Institute in Drexel’s College of Engineering. “Even more importantly,” Gogotsi adds, “on-chip energy storage is needed to create the Internet of Things - the network of all kinds of physical objects ranging from vehicles and buildings to our clothes embedded with electronics, sensors, and network connectivity, which enables these objects to collect and exchange data. This work is an important step toward that future.”
The researchers’ method for depositing carbon onto a silicon wafer is consistent with microchip fabrication procedures currently in use, thus easing the challenges of integration of energy storage devices into electronic device architecture. As part of the research, the group showed how it could deposit the carbon films on silicon wafers in a variety of shapes and configurations to create dozens of supercapacitors on a single silicon wafer.
Supercapacitors have been desirable devices to use in microelectronics because they can store a great deal of energy for their size, they can be charged and discharged their energy extremely quickly and their lifespan is nearly limitless. With this discovery, the path is clear for microchip manufacturers to take a big step forward in the way they design their products.
Beyond the energy storage applications, these carbon films offer good prospects for the development of elastic coatings with a low coefficient of friction that can be used in lubricant-free sliding parts, such as dynamic seals. They may also be used in production of membranes for gas filtration, water desalination or purification, because their pore size is in the range of single molecules. The carbon films produced by this method are quite versatile and may find applications in many areas.
Suggested Items
Altair Acquires Research in Flight, Forging a New Path for Aerodynamic Analysis
05/03/2024 | AltairAltair a global leader in computational intelligence, announced it has acquired Research in Flight, maker of FlightStream®, which provides computational fluid dynamics (CFD) software with a large footprint in the aerospace and defense sector and a growing presence in marine, energy, turbomachinery, and automotive applications.
Intel Takes Next Step Toward Building Scalable Silicon-Based Quantum Processors
05/02/2024 | BUSINESS WIRENature published an Intel research paper, “Probing single electrons across 300-mm spin qubit wafers,” demonstrating state-of-the-art uniformity, fidelity and measurement statistics of spin qubits.
Argonne, Toyota Collaborate on Cutting-Edge Battery Recycling Process
05/01/2024 | BUSINESS WIREThe U.S. Department of Energy’s (DOE) Argonne National Laboratory has recently launched a collaboration with Toyota Motor North America that could reduce the nation’s reliance on foreign sources of battery materials.
Chinese Smartphone Market Maintains its Recovery Momentum at 6.5% Growth in 1Q24,
04/26/2024 | IDCAccording to preliminary data from the International Data Corporation (IDC) Worldwide Quarterly Mobile Phone Tracker, China smartphone shipments grew 6.5% year over year (YoY) to 69.3 million units in 1Q24.
Boeing Opens Research & Technology Center in Japan
04/23/2024 | BoeingBoeing today opened a Boeing Research & Technology (BR&T) Center in Japan that will focus on innovation to enable the commercial aviation industry meet its goal of net zero carbon emissions by 2050.