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COES professor's 'metamaterials' research lands cover of international journal
September 11, 2009Dr. Dentcho Genov, an assistant professor of physics and electrical engineering at Louisiana Tech University and a Louisiana Optical Network Initiative (LONI) Institute fellow, is featured on the cover of the most recent issue of Nature Physics, one of the most respected and prestigious physics journals in the world.
Genov's groundbreaking work titled, "Mimicking celestial mechanics in metamaterials," links the newly emerging field of artificial optic materials with celestial mechanics in order to investigate celestial phenomenon in a controlled laboratory environment. Metamaterials are artificial structures that display properties beyond those available in naturally-occurring materials.
"This recognition shows the importance placed by the international physics community on the research Dr. Genov brings to Louisiana Tech," says Dr. Lee Sawyer, professor and physics program chair in Louisiana Tech's College of Engineering and Science.
Genov along with researchers from the National Science Foundation (NSF) Nanoscale Science and Engineering Center at the University of California and the Lawrence Berkeley National Laboratory in Berkeley collaborated on this article.
Using elements of Einstein's theory of relativity, this research allows scientists to observe more closely how light and matter behave around massive celestial objects such as "black holes."
The effect on light due to curved space-times generated by complex gravitational fields can now be reproduced with precisely engineered artificial optical materials, referred to in the literature as "metamaterials."
"It may be possible, in the very near future for scientists to closely study the interaction of light with strange objects such as 'black holes' or to borrow from the stability of planetary motion to create new types of near-perfect optical traps that can effectively 'store' light," says Genov.
This featured research is also closely related to technology Genov and others helped develop for the "invisibility cloak", which involves metamaterials that can conceal objects from almost anything that travels as a wave, including light, sound and, at the subatomic level, matter itself.
"The future of metamaterials for both research and application is still uncharted territory," says Sawyer. "What Dr. Genov has shown us is only the first of a wave of novel uses of these materials in the study of fundamental physics questions."
The "invisibility cloak" was ranked #7 in both Time and Discover magazines' lists of the Top 100 Science Stories of 2008.
"This recognition confirms that the engineering and science faculty at Louisiana Tech are contributing significantly to relevant and vital science discoveries," says Dr. Stan Napper, dean of Louisiana Tech's College of Engineering and Science.
"Our students are directly benefiting from these outstanding researchers who are also outstanding educators."
Louisiana Tech University
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Berkeley researchers create first hyperlens for sound waves
Ultrasound and underwater sonar devices could "see" a big improvement thanks to development of the world's first acoustic hyperlens. Created by researchers with the U.S. Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab), the acoustic hyperlens provides an eightfold boost in the magnification power of sound-based imaging technologies.
Light at the speed of a bicycle and much more
The speed of light, 300 million metres per second, was long thought an immutable constant and has defined our understanding of matter and energy but recent research in the area of optics and photonics is proving that we can manipulate light to some ingenious and hugely lucrative ends.
Beyond the looking glass
While the researchers can't promise delivery to a parallel universe or a school for wizards, books like Pullman's Dark Materials and JK Rowling's Harry Potter are steps closer to reality now that researchers in China have created the first tunable electromagnetic gateway.
The guiding of light: A new metamaterial device steers beams along complex pathways
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.
Discovery at UAB brings us nearer to making the dream of invisibility true
A group of researchers from the Department of Physics at UAB have designed a device, called a dc metamaterial, which makes objects invisible under certain light - very low frequency electromagnetic waves - by making the inside of the magnetic field zero but not altering the exterior field.
First acoustic metamaterial 'superlens' created by U. of I. researchers
A team of researchers at the University of Illinois has created the world's first acoustic "superlens," an innovation that could have practical implications for high-resolution ultrasound imaging, non-destructive structural testing of buildings and bridges, and novel underwater stealth technology.
Blurring the Line Between Magic and Science: Berkeley Researchers Create an 'Invisibility Cloak'
The great science fiction writer Arthur C. Clarke famously noted the similarities between advanced technology and magic. This summer on the big screen, the young wizard Harry Potter will once again don his magic invisibility cloak and disappear.
Nanocups brim with potential
Researchers at Rice University have created a metamaterial that could light the way toward high-powered optics, ultra-efficient solar cells and even cloaking devices.
Team develops new metamaterial device
An 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.
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Metamaterials with Negative Parameters: Theory, Design and Microwave Applications (Wiley Series in Microwave and Optical Engineering) by Ricardo Marqués (Author), Ferran Martín (Author), Mario Sorolla (Author) The first general textbook to offer a complete overview of metamaterial theory and its microwave applications Metamaterials with Negative Parameters represents the only unified treatment of metamaterials available in one convenient book. Devoted mainly to metamaterials that can be characterized by a negative effective permittivity and/or permeability, the book includes a wide overview of the most important topics, scientific fundamentals, and technical applications of metamaterials. Chapter coverage includes: the electrodynamics of left-handed media, synthesis of bulk metamaterials, synthesis of metamaterials in planar technology, microwave applications of metamaterial concepts, and advanced and related topics, includingSRR- and CSRR-based admittance surfaces, magneto-... |
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