A polymer film filled with quasi-1D TaSe3 nanowires. Photo: Zahra Barani/UC Riverside.As electronic devices saturate all corners of public and personal life, engineers are scrambling to find lightweight, mechanically stable, flexible and easily manufactured materials that can shield humans from excessive electromagnetic radiation, as well as prevent electronic devices from interfering with each other.
In a breakthrough paper in Advanced Materials, engineers at the University of California (UC), Riverside report a flexible film containing a quasi-one-dimensional (1D) nanomaterial filler, which combines excellent electromagnetic shielding with ease of manufacture.
"These novel films are promising for high-frequency communication technologies, which require electromagnetic interference shielding films that are flexible, lightweight, corrosion resistant, inexpensive and electrically insulating," said senior author Alexander Balandin, a professor of electrical and computer engineering at UC Riverside's Marlan and Rosemary Bourns College of Engineering. "They couple strongly to high-frequency radiofrequency radiation while remaining electrically insulating in direct current measurements."
Electromagnetic interference (EMI) occurs when signals from different electronic devices cross each other, affecting performance. The signal from a cell phone or laptop WiFi, or even a kitchen blender, might cause static to appear on a TV screen, for example. Likewise, airlines instruct passengers to turn off cell phones during landing and take-off because their signals can disrupt navigation signals.
Engineers long ago learned that any electrical device could possibly influence the functioning of a nearby device and developed materials to shield electronics from interfering signals. But now that electronic devices have become small, ubiquitous, wirelessly connected and critical to innumerable essential services, the opportunities for and risks of EMI-caused malfunctions have proliferated, and conventional EMI shielding materials are often insufficient. More electronic devices mean humans are also exposed to greater electromagnetic radiation than in the past. New shielding materials will be needed for the next generation of electronics.
Balandin led a team that developed the scalable synthesis of composites with unusual fillers – chemically exfoliated bundles of quasi-1D van der Waals materials. The composites demonstrated exceptional EMI shielding in the gigahertz and sub-terahertz frequency ranges important for current and future communication technologies, while remaining electrically insulating.
Graphene is the most famous van der Waals material. It is two-dimensional because it comprises a plane of strongly bound carbon atoms. Multiple planes of graphene, weakly coupled by van der Waals forces, make up a bulk graphite crystal. For many years, researchers have focused on two-dimensional layered van der Waals materials, which exfoliate into planes of atoms.
One-dimensional van der Waals materials consist of strongly bound atomic chains, rather than planes, which are weakly bound together by van der Waals forces. Such materials exfoliate into needle-like 'one-dimensional' structures rather than two-dimensional planes. The Balandin group conducted pioneering studies of 1D metals, demonstrating their unusual properties. In the new paper, the Balandin group reports using a chemical process that could be scaled up for mass production of these 1D materials.
Fariboz Kargar, a research professor and project scientist with Balandin's Phonon Optimized Engineered Materials (POEM) Center, together with doctoral student Zahra Barani, began by chemically treating the transition metal trichalcogenide TaSe3, a layered van der Waals material with a quasi-1D crystal structure. This treatment caused TaSe3 to shed needle-like, quasi-1D van der Waals nanowires with extremely large aspect ratios of up to 106 – meaning they're much longer than they are thick. In previous research, the group discovered that bundles of quasi-1D TaSe3 atomic threads can support high-current densities.
"There was no standard recipe for exfoliation of these materials," said Barani. "I did many trial and error experiments, while checking the cleavage energy and other important parameters to exfoliate them with high yield. I knew that the key is to get bundles with as high aspect ratio as I can, since EM waves couple with longer and thinner strands better. That required optical microscopy and scanning electron microscopy characterization after each exfoliation step."
The researchers filled a matrix made from a special polymer with bundles of the exfoliated TaSe3 to produce a thin, black film. These synthesized composite films, while remaining electrically insulating, demonstrated exceptional ability at blocking electromagnetic waves. Polymer composites with low loadings of the fillers were especially effective.
"The electromagnetic shielding effectiveness of composites is correlated with the aspect ratio of the fillers. The higher the aspect ratio, the lower the filler concentration needed to provide significant EM shielding," Kargar said. "This is beneficial, since by lowering the filler content one would take advantage of inherent properties of polymers such as light weight and flexibility. In this regard, I can say this class of materials are exceptional once they are exfoliated properly, controlling the thickness and length."
"In the end, I got them right, prepared a composite and measured the EMI properties. The results were amazing: no electric conductivity but more than 99.99% of EMI shielding for micrometer-thick films," Barani added.
The quasi-1D van der Waals metallic fillers can be produced inexpensively and in large quantities. Balandin said that research on atomic bundles of quasi-1D van der Waals materials as individual conductors, and on composites containing such materials, is just beginning.
"I am sure we will soon see a lot of progress with quasi-1D van der Waals materials, as happened with quasi-2D materials," he said.
This story is adapted from material from the University of California, Riverside, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.