 |
|
Team develops new metamaterial device
February 25, 2009An engineered metamaterial proved it can function as a state-of-the-art device in the complex terahertz range of the electromagnetic spectrum, setting a standard of performance for modulating tiny waves of radiation, according to a team of researchers from Boston College, the Los Alamos and Sandia national laboratories, and Boston University.
An electrical current applied to the metamaterial - a hybrid structure of metallic split-ring resonators - controlled the phase of a terahertz (THz) beam 30 times faster and with far greater precision than a conventional optical device, the researchers report in the current online edition of the journal Nature Photonics.
"This is a true metamaterial device," Boston College Asst. Prof. of Physics Willie J. Padilla, one of the co-authors of the paper, said. "This highlights the fact that you can make solid state devices at terahertz frequencies with metamaterials."
Constructed on the micron-scale, metamaterials are composites that use unique metallic contours in order to produce responses to light waves, giving each metamaterial its own unique properties beyond the elements of the actual materials in use. Within the past decade, researchers have sought ways to significantly expand the range of material responses to waves of electromagnetic radiation - classified by increasing frequency as radio waves, microwaves, terahertz radiation, infrared radiation, visible light, ultraviolet radiation, X-rays and gamma rays. These metamaterials have demonstrated numerous novel effects that defy accepted electromagnetic principles.
Previously, in systems known as THz time domain spectrometers, the flow of terahertz radiation has been modulated indirectly by optical choppers, mechanical devices that either blocked a laser or allowed it to pass through. This "all or nothing" approach - similar to opening and closing the shutter of a camera - limits the speed with which one can manipulate terahertz waves since the chopper's mechanical components are too slow, Padilla says.
The metamaterial devised by the research team electronically controlled the flow of terahertz radiation over roughly 70 percent of the frequency band - not simply at the points of maximum or minimum frequency.
"We can apply an electronic signal to this device, thus making it opaque to stop terahertz, or transparent to allow terahertz through," Padilla said. "Eventually, you can turn it on and off very quickly - and that allows you to modulate the beam at a very specific frequency."
Because the metamaterial device is solid-state, eliminating moving parts, it is 30 times faster than the optical chopper, according to the report, co-authored by Hou-Tong Chen, Abul K. Azad and Antoinette J. Taylor of Los Alamos National Laboratory, Michael J. Cich of Sandia National Laboratories and Richard D. Averitt of Boston University
"The advantage of the metamaterial is you are doing it electronically," Padilla said. "If you want to build a device, the advantage of this is that it is all solid-state and voltage controlled. You have no moving parts. Therefore, you can modulate at very high speeds."
These kinds of controls have been developed for microwave and optical frequencies and led to a number of key breakthroughs, the researchers note. But the technologies have not extended to the terahertz frequency.
Padilla said a solid-state metamaterial device is a critical step toward improved terahertz devices, such as cameras or scanners.
"What we've shown with this metamaterial is that it is now improved to the point where it could be used as a device," Padilla said. "It could be the device you could use to build a terahertz system."
Boston College
More Metamaterial Device Current Events and Metamaterial Device News Articles
 |
Terahertz Plasmonics: Metamaterials and Guided-wave Devices by Amit Agrawal (Author), Ajay Nahata (Author) Over the last half century, developments in optics have fundamentally transformed the way we live. For example, optical communications has helped bring people across the globe closer, while consumer electronics, in the form of CDs and DVDs, have allowed us to store, access, and share information on a scale that was believed unattainable several decades ago. While innumerable technologies have been developed across the electromagnetic spectrum, one specific frequency band has largely been underdeveloped. The far-infrared or terahertz (THz) frequency range has often been referred to as the ¿gap¿ in the electromagnetic spectrum. This book describes our research in exploring the physics and applications of resonance phenomena at THz frequencies using surface plasmon based... |
 |
Metamaterial: Negative index metamaterials, Negative refraction, Cloaking device, METATOY, Electronic band structure, Oscillation, Gauss's law, Poisson's ratio, Superlens by Frederic P. Miller (Editor), Agnes F. Vandome (Editor), John McBrewster (Editor) Metamaterial. Negative index metamaterials, Negative refraction, Cloaking device, METATOY, Electronic band structure, Oscillation, Gauss's law, Poisson's ratio, Superlens, Fresnel lens, Phonon, Surface phonon, Photonic crystal |
 |
Nonlinearities in Periodic Structures and Metamaterials (Springer Series in Optical Sciences) by Cornelia Denz (Editor), Sergej Flach (Editor), Yuri S. Kivshar (Editor) Optical information processing of the future is associated with a new generation of compact nanoscale optical devices operating entirely with light. Moreover, adaptive features such as self-guiding, reconfiguration and switching become more and more important. Nonlinear devices offer an enormous potential for these applications. Consequently, innovative concepts for all-optical communication and information technologies based on nonlinear effects in photonic-crystal physics and nanoscale devices as metamaterials are of high interest. This book focuses on nonlinear optical phenomena in periodic media, such as photonic crystals, optically-induced, adaptive lattices, atomic lattices or metamaterials. The main purpose is to describe and overview new physical phenomena that result... |
 |
Metamaterials: Critique and Alternatives by Benedikt A. Munk (Author) A Convincing and Controversial Alternative Explanation of Metamaterials with a Negative Index of Refraction In a book that will generate both support and controversy, one of the world's foremost authorities on periodic structures addresses several of the current fashions in antenna design—most specifically, the popular subject of double negative metamaterials. Professor Munk provides a comprehensive theoretical electromagnetic investigation of the issues and concludes that many of the phenomena claimed by researchers may be impossible. While denying the existence of negative refraction, the author provides convincing alternative explanations for some of the experimental examples in the literature. Although the debate on this subject is just beginning, Professor Munk... |
 |
Metamaterials and Plasmonics: Fundamentals, Modelling, Applications (NATO Science for Peace and Security Series B: Physics and Biophysics) by Saïd Zouhdi (Editor), Ari Sihvola (Editor), Alexey P. Vinogradov (Editor) Metamaterials and plasmonics are cross-disciplinary fields that are emerging into the mainstream of many scientific areas. Examples of scientific and technical fields which are concerned are electrical engineering, micro- and nanotechnology, microwave engineering, optics, optoelectronics, and semiconductor technologies. In plasmonics, the interplay between propagating electromagnetic waves and free-electron oscillations in materials are exploited to create new components and applications. On the other hand, metamaterials refer to artificial composites in which small artificial elements, through their collective interaction, creates a desired and unexpected macroscopic response function that is not present in the constituent materials. This book charts the state of the... |
 |
Metamaterials: Theory, Design, and Applications by Tie Jun Cui (Editor), David R. Smith (Editor), Ruopeng Liu (Editor) Metamaterials:Theory, Design, and Applications goes beyond left-handed materials (LHM) or negative index materials (NIM) and focuses on recent research activity. Included here is an introduction to optical transformation theory, revealing invisible cloaks, EM concentrators, beam splitters, and new-type antennas, a presentation of general theory on artificial metamaterials composed of periodic structures, coverage of a new rapid design method for inhomogeneous metamaterials, which makes it easier to design a cloak, and new developments including but not limited to experimental verification of invisible cloaks, FDTD simulations of invisible cloaks, the microwave and RF applications of metamaterials, sub-wavelength imaging using anisotropic metamaterials, dynamical metamaterial systems,... |
 |
Optical Metamaterials: Fundamentals and Applications by Wenshan Cai (Author), Vladimir Shalaev (Author) Metamaterials—artificially structured materials with engineered electromagnetic properties—have enabled unprecedented flexibility in manipulating electromagnetic waves and producing new functionalities. This book details recent advances in the study of optical metamaterials, ranging from fundamental aspects to up-to-date implementations, in one unified treatment. Important recent developments and applications such as superlens and cloaking devices are also treated in detail and made understandable. The planned monograph can serve as a very timely book for both newcomers and advanced researchers in this extremely rapid evolving field. |
 |
Porous Semiconductors: Optical Properties and Applications (Engineering Materials and Processes) by Vladimir Kochergin (Author), Helmut Föll (Author) Porous Semiconductors: Optical Properties and Applications provides an examination of porous semiconductor materials. Beginning with a description of the basic electrochemistry of porous semiconductors and the different kinds of porous semiconductor materials that can be fabricated, the book moves on to describe the fabrication processes used in the production of porous semiconductor optical components. Concluding the text, a number of optical components based on porous semiconductor materials are discussed in depth. Porous Semiconductors: Optical Properties and Applications provides a thorough grounding in the design, fabrication and theory behind the optical applications of porous semiconductor materials for graduate and undergraduate students interested in optics, photonics,... |
 |
Optical Micro and Nano Technology by Jung-Chih Chiao (Author) Complete coverage of optical micro-/nanotechnology, from the fabrication of micro-/nanoscale devices to the variety of applications With contributions from renowned industry experts, this is a one-stop resource for optical micro and nanotechnology. Each chapter focuses on a separate device, systematically covering the fundamentals, fabrication, device characterization, existing applications, and future applications. Optical Micro and Nanotechnology includes details on devices ranging from nano-sensing devices to optical MEMS/MOEMS to photonic microresonators. The book also offers extensive coverage of photonic meta-materials, and includes hundreds of illustrations. . |
| © 2009 BrightSurf.com |