Using a composite metamaterial to deliver a complex set of instructions to a beam of light, Boston College physicists have created a device to guide electromagnetic waves around objects such as the corner of a building or the profile of the eastern seaboard. As directed by the researchers’ novel device, the beams continue to behave as if traveling in a straight line. In one computer simulation, Willie J. Padilla, assistant professor of physics, and researcher Nathan Landy revealed that the device could steer a beam of light along the boundary of the US, stretching from Michigan to Maine, down the seaboard, around Florida and into the Louisiana bayou. They accomplished their feat by developing a much more precise set of instructions, which create a gridlike road map capable of twisting and turning a beam of light around objects or space. Their discovery is an extension of earlier metamaterial “cloaking” techniques. Padilla and Landy report developing a space-mapping technique that delivers greater precision and efficiency guiding light along pathways that previously were too complex to sustain – from 90° angles to the rugged coastal profile of Maine. Furthermore, they built the device using relatively common dielectric materials such as silicon. Boston College researchers report developing a device that can bend light along complex pathways. An illustration shows a simulated electromagnetic wave propagation. Guided by a set of instructions delivered by the device, the wave curves around the profile of the eastern US while behaving as if traveling in a straight line. (Image: Optics Express) “Our method combines the novel effects of transformational optics with the practicality of dielectric construction,” Padilla and Landy report. “We show that our structures are capable of guiding light in an almost arbitrary fashion over an unprecedented range of frequencies.” The discovery builds upon a decade-long revolution in electromagnetics brought about by the emergence of metamaterials. Constructed from artificial composites, metamaterials have exhibited effects such as directing light at a negative index of refraction. Researchers have combined metamaterials with artificial optical devices – also known as transformational optics – to demonstrate the “invisibility cloak” effect, essentially directing light around a space and effectively masking its existence. In addition, other researchers have used a method known as quasi-conformal mapping and very complex metamaterials to issue a somewhat imprecise set of instructions that create another space-cloaking effect. This research was published in the journal Optics Express. For more information, visit: www.bc.edu