Metamaterials are artificially structured materials designed to control and manipulate physical phenomena such as light and other electromagnetic waves, sound waves and seismic waves in unconventional ways, resulting in exotic behavior that’s not found in nature. They are predicted to be able to protect the building from earthquakes by bending seismic waves around it, Similarly, tsunami waves could be bent around towns, and sound waves could be bent around a room to make it soundproof.
Metamaterials (i.e., engineered electromagnetic structures), are poised to disrupt industries, create entirely new markets, and change society. The ability to design and fabricate materials with new functionalities opens the door to a new world of possibilities. They can be tailored to either augment the functionality of existing devices or create new devices with superior performances. Metamaterials are utilized in various devices including Sensors, Superlensing, Cloaking, and Light emitting diodes. Metamaterials are utilized across various applications, including high frequency battle field communication, sensor detection, improving ultrasonic sensors, solar power management, and high gain antennas and also in various remote aerospace applications.
Researchers are developing passive radiative cooling (self-cooling films) for buildings and power plant cooling; electronically scanned array platform for drones and self-driving cars; smart metamaterial antennas for 5G networks and satellites; metasurfaces for molding the flow of light; thermal barriers for energy-efficient single pane windows; RF energy harvesting platform for IoT; peripheral nerves/brain focused magnetic stimulation (FMS) technologies; thermophotovoltaics devices; multispectral imaging chemical sensor; and a state-of-the-art computational electromagnetics simulation platform.
“The idea behind metamaterials is to mimic the way atoms interact with light, but with artificial structures much smaller than the wavelength of light itself,” said Boris Kuhlmey from the University of Sydney. This way, their properties are derived from both the inherent properties from their base materials as well as the way they are assembled, such as the design of their shape, geometry, size, orientation and arrangement. Thus optical properties are no longer restricted to those of the constituent materials, and can be designed almost arbitrarily.
Typically, metamaterials include several classes of electromagnetic composites including negative index materials, photonic crystals, zero index materials, low index materials and chiral metamaterials. Some of the prominent modeling methods of metamaterials are finite difference time domain (FDTD) method, finite-element method (FEM), and transmission line method (TLM).
Engineers at the University of California San Diego have fabricated the first semiconductor-free, optically-controlled microelectronic device. Using metamaterials, engineers were able to build a microscale device that shows a 1,000 percent increase in conductivity when activated by low voltage and a low power laser. The device consists of an engineered surface, called a metasurface, on top of a silicon wafer, with a layer of silicon dioxide in between. The metasurface consists of an array of gold mushroom-like nanostructures on an array of parallel gold strips.
The gold metasurface is designed such that when a low DC voltage (under 10 Volts) and a low power infrared laser are both applied, the metasurface generates “hot spots”—spots with a high intensity electric field—that provide enough energy to pull electrons out from the metal and liberate them into space. “This certainly won’t replace all semiconductor devices, but it may be the best approach for certain specialty applications, such as very high frequencies or high power devices,” leder of the group and electrical engineering professor Dan Sievenpiper at UC San Diego Sievenpiper said.
Researchers at Michigan Technological University in continuation of work done by Durdu Güney, a professor of electrical and computer engineering have found a way to pass light waves to pass through the lens without getting absorbed. They utilized metamaterials based on thin silver films tweaked at the subwavelength scale so that light waves pass through instead of reflecting off the metal.
“Aluminum and silver are the best choices so far in the visible light spectrum, not just for a perfect lens but all metamaterials,” Güney says, explaining that metamaterials have been successfully created with these metals, although they still tend to absorb light waves. “Loss—or the undesired absorption of light—is good in solar cells, but bad in a lens because it deteriorates the waves,” he explains.
Optical Computer Networks
In 2012, the Berkeley Nanosciences and Nanoengineering Institute published a paper with South Korean scientists describing a metamaterial-based electro-optical modulator made from a sheet of graphene just a single atom thick that was able to switch lightwaves at terahertz frequencies.
More recently, a group at City College of New York, led by the physicist Vinod Menon, demonstrated light emission from ultrafast-switching LEDs based on metamaterials. Together, such innovations could make possible optical computer networks far faster than today’s gigabit networks.
Acoustic metamaterials are artificially fabricated materials designed to control, direct, and manipulate sound waves. More recently, the metamaterial concept has been extended to acoustic waves in a variety of scenarios of interest such as acoustic clocking, super-lensing and sound focusing and confinement.
Prof Katia Bertoldi of Harvard University also studies strange, elastic materials like this, which have a negative “Poisson ratio”. This means that when you compress them, instead of squashing out to the sides and getting both flatter and wider, they actually shrink in all directions.
Then when stretched, they expand in all directions. Prof Bertoldi’s team has engineered various useful properties into such materials, including making them absorb sound at different frequencies when squeezed. The Poisson ratio can also affect fatigue in a metal – so she has worked with Rolls Royce to design engine components with complex slits wound into them, which withstand many more cycles of compression before breaking.
New metamaterial enhances natural cooling without power input
A team at the University of Colorado Boulder (CU-Boulder) in the US developed a new metamaterial film out of glass microspheres, polymer and silver, that provides cooling without needing a power input. Radiative cooling is the natural process through which objects shed heat in the form of infrared radiation. The challenge for the CU-Boulder researchers was to create a material that both reflects sunlight and also allows infrared emission.
Aircraft manufacturer Airbus announced that it was joining with Lamda Guard, a Canadian company, to test a metamaterial-based coating for cockpit windows to protect pilots in commercial aircraft from being blinded by laser pointers. There are obvious markets for the technology in automotive safety and self-driving cars. Google’s advanced experimental vehicles use a costly mechanical laser-based device called a lidar to create an instantaneous high-resolution map of objects around the car. Based on a rapidly spinning laser, Google’s lidars still cost roughly $8,000. The radars being designed by Echodyne may soon be able to create similar maps at a much lower cost.
Kymeta and Evolv Technology, are also working on other metamaterial-based applications. Evolv is pursuing higher-performance airport-security-scanning technology, and Kymeta recently announced a partnership with Intelsat to design land-based and satellite-based intelligent antennas that would greatly increase the capacity and speed of next-generation satellite Internet services.
Elena Semouchkina, a pioneer on cloaking devices at Michigan Technological University, points to screening antennas so they don’t interfere with each other, protecting people from harmful radiation or acoustic pressure and even preventing buildings from destruction from seismic waves.
Intel Metamaterials Breakthrough, “Sub-millimeter EMI Shunt Beats Shields”
A metamaterial breakthrough has been funded by Intel at the Electromagnetic Compatibility (EMC) Lab at National Taiwan University. By folding a metamaterial up into the third dimension (3D), a breakthrough in suppression of electro-magnetic interference (EMI) has been achieved enabling easier electro-magnetic compatibility (EMC) of next-generation high-speed interfaces.
The Intel/NTU’s breakthrough is a single sub-millimeter sized component that replaces bulky traditional shielding by suppressing noise at each source by 20dB, according to Professor Tzong-Lin Wu, an IEEE Fellow and Director of the Graduate Institute of Communication Engineering (GICE) at NTU. In addition to 20-dB noise suppression, more than one can be placed in-line with the high-speed transmission line to achieve 40db (with two), 60dB (with three) and so forth.
“Along with the vigorous development of cloud computing, it is of vital importance to enhance the bandwidth and efficiency of data centers and their communication devices for next-generation communication,” Wu told EE Times in an exclusive interview. “New high-speed signal transmission design and high-frequency noise suppression technologies are key to enabling wider data bandwidth in cloud computing and other applications.”
The tiny metamaterial components–measuring just 1.0-by-0.8-by-0.6 millimeters–are folded like origami to suppress EMI problems in high-speed interfaces whose wavelength is much longer than the physical size of the noise suppression component. Due to a widely used ceramic or PCB manufacturing process, they are also much cheaper than tradition shielding techniques for any electronic component with external interfaces.
The NTU EMC Lab claims to be the first to use the invention of planar electromagnetic band-gap (EBG) power planes to suppress switching noise of packaged circuits, and now has a new claim–the first use of metamaterial differential transmission lines to virtually eliminate common-mode noise in high-speed differential signals.
The next likely consumer use of metamaterials could be in the wireless charging of devices, an area attracting keen industry attention. Samsung Electronics has filed several patents related to metamaterials and wireless charging.
Mechanically Programmable Materials
Bastiaan Florijn, a final-year PhD student at Leiden University in the Netherlands, demonstrated what he calls the first ever mechanically “programmable” material. It is a surprisingly low-tech looking slab of rubber, punched with an array of holes. But those holes, of two sizes, are specifically designed so that they can compress either vertically or sideways – and that switch is controlled by adding a small clamp.
The end result is a sort of oversized sponge that can be stiff, or soft, or flit between the two at a specific stage of the squeeze. If it switches to become softer while still under pressure, this is known as “negative stiffness” – a property so weird that Mr Florijn said he still hasn’t worked out an application for it.
But the slabs have another property that could be immensely useful: they absorb energy. “Imagine a car bumper that you can program – for instance, if you drive in a neighbourhood with a lot of small kids, you want to have a very soft bumper,” Mr Florijn said. “But then if you’re going fast on the highway, you want it to be stiff.” He and his colleagues are also talking to shoe companies, who are interested in producing soles that adjust to different terrain.
Cristian Della Giovampaola and Nader Engheta from the University of Pennsylvania propose using just two subunits with opposing properties. Called “metamaterial bits,” these are like the 1s and 0s in a binary code. They used nano-sized pieces of silver and silica, which interact with light in very different ways: One’s a metal, the other’s an insulator.
The duo used a computer simulation to create layered structures that constitute bytes of increased functionality and complexity. Once they were “digitized,” the resulting material had its own unique properties, distinct from its constituent subunits.
Metamaterials based Simple Machines by 3D Printing
“So far, metamaterials were understood as materials—we want to think of them as machines. We demonstrate metamaterial objects that perform a mechanical function,” says Hasso Plattner Institute, Potsdam, Germany. Such metamaterial mechanisms consist of a single block of material the cells of which play together in a well-defined way in order to achieve macroscopic movement. Our metamaterial door latch, for example, transforms the rotary movement of its handle into a linear motion of the latch. Our metamaterial Jansen walker consists of a single block of cells—that can walk. The key element behind our metamaterial mechanisms is a specialized type of cell, the only ability of which is to shear.
“In order to allow users to create metamaterial mechanisms efficiently we implemented a specialized 3D editor. It allows users to place different types of cells, including the shear cell, thereby allowing users to add mechanical functionality to their objects. To help users verify their designs during editing, our editor allows users to apply forces and simulates how the object deforms in response.”
Metamaterial-enabled devices have a wide range of applications in the RF, THz, IR, and visible spectrum.
China has begun to make breakthroughs in its research into metamaterials, inching closer to the People’s Liberation Army’s dream of developing an “invisible” aircraft, reports the Beijing-based Sina Military Network. China’s 863 Program (State High-Tech Development Plan), 973 Program (National Basic Research Program) and the National Natural Science Foundation of China are all receiving government funding to explore the field.
According to the report, the potential applications and projects of metamaterials being considered by Chinese researchers are extremely broad, and include notebook-sized satellite antennae, flexible ceramics, defensive walls that can reduce the impact of earthquakes and tsunamis, smart shoes capable of sensing terrain, and of course, invisible planes.
One of the breakthroughs achieved by Liu Ruopeng, president of the Shenzhen-based Kuang-Chi Institute of Advanced Technology and his team is Meta-RF technology. Based on a complex electromagnetic structure design, the technology controls and modulates the transmission of electromagnetic waves with high accuracy. This has allowed China to gain a leg-up over competitors in the metamaterials sector, Sina Military said.
Using Meta-RF technology, Kuang-Chi has developed electromagnetic metamaterial antennas, which can launch energy into free space and has applications in wireless communication, space communications, GPS, satellites, space vehicle navigation and airplanes. Using a circuit board that can be folded to the size of a notebook, the technology enables devices to connect to satellite broadband internet from airplanes, trains, boats and cars from remote locations. The advantage of the antennae is that they can detect satellites anywhere, unlike traditional dish-shaped antennae that are locked in to point at one particular satellite.
Kuang-Chi already tested the technology in 22 Chinese provinces as early as three years ago, while the US is only starting to be commercialize the technology this year. Founded in 2010, Kuang-Chi has applied for more than 2,800 patents, 86% of which are linked to the metamaterials materials industry.
Military is also interested in metamaterials primarily for cloaking, to make their platforms, weapons and persons invisible from electro-optic sensors, radars and sonars. They may also be used for camouflage making one object look like another, looking to disguise fighter jets as freighters. Applications shall lead to new means of signature control, the development of low-probability intercept active sensors, the application of high-resolution planar lenses, and the use of compact antennas. Experts think radar antennas and absorbers as the most promising defence applications. On the other hand, wide-band tunable surfaces are the most wanted applications of metamaterials, although they are far to be achieved.
Flexible material to protect buildings, military personnel from earthquakes
A cloak is a coating material that makes an object indistinguishable from its surroundings or undetectable by external field measurements. Guoliang Huang, the James C. Dowell Professor in the Department of Mechanical and Aerospace Engineering, said these types of cloaking materials are mature, in the technical sense, because the properties of acoustic (radar, sonar) and optical waves (infrared) are well-understood.
However, Huang said little to no work has succeeded in solving the problem of cloaking for elastic waves in solid media, such as a seismic wave propagated through the ground. Recently, Huang, along with his former postdoc and students Assistant Professor Hussein Nassar and Research Assistant Professor Yangyang Chen, has designed and created a new metamaterial, an artificially structured material, that achieves “perfect” elastic material cloaking.
“This material is both theoretical and experimental—we created it in our lab,” Huang said. “We call it ‘polar material’ because we realized it has internal torque. We are the first to propose the principles of this material and also the first to design and fabricate this material. The concept is, if you have an object you want to make invisible, you design some kind of coating material around the object so that when a wave hits the object, if passes around the material with no refraction.”
Huang said there is no natural material that satisfies the long-standing problem of transformation-invariance, wherein non-standard properties are needed after certain transformations. He said the ultimate purpose of his research is to model, design and fabricate materials that will fill in this “behavioral gap.” The new class of cloaking or polar materials his team created is composed of a functionally graded lattice embedded in an isotropic continuum background. The layers were 3-D printed and manually assembled.
“We experimentally and numerically investigated the characteristics of the proposed cloak and found very good cloaking performance under both tension and shear loadings,” Huang wrote in his paper, one of two research papers Huang and his team had published by the Physical Review of Letters on the subject of polar materials. In addition to protecting structures against seismic waves, Huang said another potential application of the new metamaterial would be suppressing vibrations on engines to reduce noise.
“If you want to hide something in solid media, this is different,” Huang said. “In solid media, the wave is more complicated than the radar wave because in solid media we not only have a compression wave but we also have a shear wave. In civil engineering, we deal with earthquakes—seismic waves, which have longitudinal and shear waves, and most of the damage is cause by the shear wave.”
“The results that the University of Missouri team has recently published are encouraging,” said Dr. Dan Cole, program manager, Army Research Office, an element of the U.S. Army Combat Capabilities Development Command’s Army Research Laboratory. “This research could lead to new strategies for steering mechanical waves away from critical regions in solid objects, which could enable novel capabilities in soldier protection and maneuvers.”
The global Metamaterials Market size was valued at USD 658.3 million in 2019 and is anticipated to reach USD 3.61 billion by 2027 at a CAGR of 23.6%. Amid the COVID-19 crisis, the global market for Metamaterials estimated at US$334. 9 Million in the year 2020, is projected to reach a revised size of US$5
The key factors influencing the market include increasing demand for the new technologies that can be used in many applications such as absorbers, superlenses, and antennas instead of the conventional materials in order to boost the performance of the machinery and reliability of overall processes across applications.
Increasing demand from various end-use industries, including consumer electronics and medical, is driving the growth of the market. In addition, growing application scope in the aerospace & defense industry is expected to further fuel the demand growth during the forecast period. The major factors driving the growth of the metamaterial market include variety in design functionalities, anti-glare coating applications, and invisibility cloak for stealth aircraft.
The uniquely engineered synthetic structures having superior electromagnetic properties find a wide range of applications and a vast potential for usage in large end-use verticals such as automotive, consumer electronics, provide better imaging in medical equipment, energy & power, aerospace & defense, and others. The metamaterial market is driven mainly by demand from telecommunications applications because of the potential of the material to be used in devices, such as radars.
The aerospace & defense end-use sub-segment is considered to be the largest end-use segment in terms of revenue, and this domination is projected to continue in the forecast period, owing to the fast development of this end-user vertical in core economies such as the U.S., the U.K., Germany, China, India, and Russia. The antenna sub-segment is expected to accumulate a steady growth rate over the forecast period, primarily owing to an increased demand for specialized antennas in applications, especially in defense, aerospace, & telecommunications.
The absorber sub-segment products are used in the manufacture of products such as cloaking systems, super, and lenses. The advantages of using metamaterials in the antenna and absorber segments help make it one of the higher revenue-generating segments.
The Terahertz sub-segment is expected to grow fastest in Metamaterials market during the projected period.
The terahertz metamaterial products which are engineered specifically to interact at the terahertz frequencies such as Microwave & the infrared wavelengths ranging from 0.1 to 10 THz, are widely being in use in the spectroscopy and in the remote sensing technology and also widely helping in lifting the overall market growth.
Photonic Segment to Record 48.7% CAGR
In the global Photonic segment, USA, Canada, Japan, China and Europe will drive the 47.1% CAGR estimated for this segment. These regional markets accounting for a combined market size of US$27.4 Million in the year 2020 will reach a projected size of US$408.6 Million by the close of the analysis period. China will remain among the fastest growing in this cluster of regional markets. Led by countries such as Australia, India, and South Korea, the market in Asia-Pacific is forecast to reach US$931 Million by the year 2027, while Latin America will expand at a 51.4% CAGR through the analysis period. We bring years of research experience to this 9th edition of our report. The 298-page report presents concise insights into how the pandemic has impacted production and the buy side for 2020 and 2021. A short-term phased recovery by key geography is also addressed.
In terms of sales, North America dominates the industry, and this pattern is forecasted to continue throughout the forecast period. The rising demand for the products from a various end-use industries, including the aerospace & defense, is expected to fuel regional market growth.
The Metamaterials market in the U.S. is estimated at US$89.5 Million in the year 2020. China, the world`s second largest economy, is forecast to reach a projected market size of US$1.5 Billion by the year 2027 trailing a CAGR of 58.7% over the analysis period 2020 to 2027. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at 40.4% and 45.6% respectively over the 2020-2027 period. Within Europe, Germany is forecast to grow at approximately 42.7% CAGR.
The Asia Pacific area is predicted to accelerate with the fastest growth rate during the forecast period. The rapid development of the medical, aerospace & defense, and consumer electronics, sectors in the Asia Pacific region, which are mostly driven by the countries namely China and India, is registering to have the positive impacts on the overall worldwide market growth throughout the forecast period. The developing regions in Asia Pacific are experiencing a rapid industrialization, urbanization, and huge economic development, and a mentionable shift in the consumer taste & preferences, and an increased understanding of energy conservation, which commands the need for metamaterials.
The global business landscape of Metamaterial remains quite dynamic with increasing numbers of small, medium as well as large companies. Enormous competition for technological innovation and higher diversification will offer tremendous opportunities for creative players over the forecast timeframe.
In September 2019, a joint venture of the Caltech-Georgia Tech Zurich team developed a modern type of architected Metamaterial, which has the ability to shape change in a tunable method.
Key players in the market include Aegis Technologies Group, Applied EM, Inc., Jem Engineering, LLC.Metamaterial Technologies, Inc., MetaShield LLC., Metamagnetics, Inc., Kymeta Corporation, MediWise Ltd., Phoebus Optoelectronics LLC, JEM Engineering, LLC, Multiwave Technologies AG, Echodyne, Inc., Nanohmics, Inc., Nanosonic Inc., Plasmonics, Inc., Teraview Ltd., NKT Photonics AS, and Fractal Antenna Systems Inc., among others.
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