Matthew Griffin, award winning Futurist and Founder of the 311 Institute, a global futures think tank, is described as "The Adviser behind the Advisers." Regularly featured on AP, CNBC, Discovery and RT, his ability to identify and track hundreds of game changing emerging technologies, and explain their impact on global culture, industry and society, is unparalleled. Recognised for the past five years running as one of the world's foremost futurists, innovation and strategy experts Matthew is an international speaker who helps governments investors, multi-nationals and regulators around the world envision, build and lead an inclusive future. A rare talent Matthew sits on the Technology and Innovation Committee (TIAC) for Centrica, one of Europe’s largest energy companies, and his recent work includes mentoring XPRIZE teams, building the first generation of biocomputers, helping the world’s largest manufacturers companies envision the next five generations of smartphones and devices, and what comes next, and helping companies including Qualcomm envision the next twenty years of semiconductors. Matthew's clients are the who’s who of industry and include Accenture, Bain & Co, BOA, Blackrock, Bloomberg, Booz Allen Hamilton, BCG, Bentley, Dell EMC, Dentons, Deloitte, Deutsche Bank, Du Pont, E&Y, Fidelity, Goldman Sachs, HPE, Huawei, JPMorgan Chase, KPMG, Lloyds Banking Group, McKinsey, Monsanto, PWC, Qualcomm, Rolls Royce, SAP, Samsung, Schroeder's, Sequoia Capital, Sopra Steria, UBS, the UK's HM Treasury, the USAF and many others.
WHY THIS MATTERS IN BRIEF
It’s not just our devices that are getting smaller and more powerful, the components that make our devices are also going through their own revolutions.
Recently I discussed how a new Metalense breakthrough from Harvard University will help us realise atomic sized camera lenses, and now researchers elsewhere in the US have unveiled a new membrane based nanoantenna nearly 100 times smaller than the most compact current antenna. These antennas could find use in portable wireless communications systems, including bio-implantable antennas, bio-injectable antennas, bio-ingestible antennas, Internet of Things, smartphones, smart pills, and wearable electronics, the researchers say, and lest we forget, they could also one day end up in tomorrow’s nanobots and nanomachines, like these ones that will swim around our bloodstream… and more.
Today’s state-of-the-art compact antennas are designed to resonate at specific wavelengths, but their miniaturization is limited to roughly one-tenth of their resonant wavelengths, but the new antennas developed by researchers at Northeastern University and their collaborators can now be shrunk to sizes as small as one-thousandth of the wavelength they aim to receive and transmit, and all, importantly, without any degradation in performance. The researchers detailed their findings online in the journal Nature Communications.
These new antennas consist of thin membranes made up of two different kinds of films. Its piezomagnetic iron-gallium-boron layers convert mechanical oscillations to magnetic signals and vice versa. They are paired with piezoelectric aluminum nitride films, which convert mechanical oscillations to electrical signals and vice versa.
When these membranes receive electromagnetic signals, their magnetic layers sense the magnetic fields of these electromagnetic waves. This causes the membranes to vibrate, which piezoelectrically generates a voltage.
Conversely, in order for the antennas to transmit, they vibrate. This causes the magnetic layers of the membranes to generate a magnetic current that radiates electromagnetic waves.
The sizes of these “magnetoelectric” antennas depend on the wavelengths of the acoustic vibrations they operate with instead of the electromagnetic signals they receive and transmit. Because these acoustic wavelengths are about 100,000 times shorter than their corresponding electromagnetic wavelengths, these new antennas can be much smaller than conventional antennas.
“This acoustic antenna concept changes the fundamental principle on which antennas have been designed for over a century, and can lead to dramatically compact antennas with improved performance,” says study senior author Nian-Xiang Sun, an electrical engineer and materials scientist at Northeastern.
In experiments, these nanoelectromechanical system (NEMS) antennas could receive and transmit at VHF and UHF radio frequencies. In addition, they are completely passive, requiring simple electronics and no battery.
Future research will attempt to improve antenna performance through new materials, new designs and better fabrication processes, Sun says.
“These are the first magnetoelectric antennas that have been demonstrated, which are not perfect,” he says, “we see a lot of room of improvement.”