 |
|
Visualizing atomic-scale acoustic wavesin nanostructures
July 07, 2008LIVERMORE, Calif. - Acoustic waves play many everyday roles - from communication between people to ultrasound imaging. Now the highest frequency acoustic waves in materials, with nearly atomic-scale wavelengths, promise to be useful probes of nanostructures such as LED lights.
However, detecting them isn't so easy.
Enter Lawrence Livermore National Laboratory scientists, who discovered a new physical phenomenon that enables them to see high frequency waves by combining molecular dynamics simulations of shock waves with an experimental diagnostic, terahertz (THz) radiation. (The hertz is the base unit of frequency. One hertz simply means one cycle per second. A terahertz is 10^12 hertz.).
The Livermore scientists performed computer simulations of the highest frequency acoustic waves forming spontaneously at the front of shock waves or generated by sub-picosecond pulse-length lasers.
They discovered that, under some circumstances, when such a wave crosses an interface between two materials, tiny electric currents are generated at the interface. These currents produce electromagnetic radiation of THz frequencies that can be detected a few millimeters away from the interface. Part of the wave is effectively converted to electromagnetic radiation, which propagates out of the material where it can be measured.
Most molecular dynamics simulations of shock waves connect to experiments through electronic properties, such as optical reflectivity.
"But this new approach connects to the much lower frequency THz radiation produced by the individual atoms moving around in the shock wave," said Evan Reed, lead author of a paper that appears in the July 7 edition of the journal, Physical Review Letters. "This kind of diagnostic promises to provide new information about shocked materials like the dynamics of crystals pushed to ultra-high strain rates."
Using molecular dynamics simulations, the team, made up of Livermore's Reed and Michael Armstrong in collaboration with Los Alamos National Laboratory colleagues shows that the time-history of the wave can be determined with potentially sub-picosecond, nearly atomic time and space resolution by measuring the electromagnetic field.
Reed and colleagues studied the effect for an interface between two thin films, which are used in LED (light-emitting diode) nanostructures, and are piezoelectric (electric currents that are generated when they are squeezed). Piezoelectric materials have been used for decades as arrival time gauges for shock-wave experiments but have been limited by electrical equipment that can only detect acoustic frequencies less than 10 gigathertz (GHz), precluding observation of the highest frequency acoustic waves. The new THz radiation technique can help improve the time resolution of such approaches.
The technique has other applications as well. It can be applied to determine the structure of many kinds of electronic devices that are constructed using thin film layered structures, such as field-effect transistors.
"The detection of high frequency acoustic waves also has been proposed for use in imaging of quantum dot nanostructures used in myriad optical devices, possibly including solar cells in the future," Reed said. "The technology is not there yet for that application, but our work represents a step closer."
DOE/Lawrence Livermore National Laboratory
The Livermore scientists performed computer simulations of the highest frequency acoustic waves forming spontaneously at the front of shock waves or generated by sub-picosecond pulse-length lasers.
They discovered that, under some circumstances, when such a wave crosses an interface between two materials, tiny electric currents are generated at the interface. These currents produce electromagnetic radiation of THz frequencies that can be detected a few millimeters away from the interface. Part of the wave is effectively converted to electromagnetic radiation, which propagates out of the material where it can be measured.
Most molecular dynamics simulations of shock waves connect to experiments through electronic properties, such as optical reflectivity.
"But this new approach connects to the much lower frequency THz radiation produced by the individual atoms moving around in the shock wave," said Evan Reed, lead author of a paper that appears in the July 7 edition of the journal, Physical Review Letters. "This kind of diagnostic promises to provide new information about shocked materials like the dynamics of crystals pushed to ultra-high strain rates."
Using molecular dynamics simulations, the team, made up of Livermore's Reed and Michael Armstrong in collaboration with Los Alamos National Laboratory colleagues shows that the time-history of the wave can be determined with potentially sub-picosecond, nearly atomic time and space resolution by measuring the electromagnetic field.
Reed and colleagues studied the effect for an interface between two thin films, which are used in LED (light-emitting diode) nanostructures, and are piezoelectric (electric currents that are generated when they are squeezed). Piezoelectric materials have been used for decades as arrival time gauges for shock-wave experiments but have been limited by electrical equipment that can only detect acoustic frequencies less than 10 gigathertz (GHz), precluding observation of the highest frequency acoustic waves. The new THz radiation technique can help improve the time resolution of such approaches.
The technique has other applications as well. It can be applied to determine the structure of many kinds of electronic devices that are constructed using thin film layered structures, such as field-effect transistors.
"The detection of high frequency acoustic waves also has been proposed for use in imaging of quantum dot nanostructures used in myriad optical devices, possibly including solar cells in the future," Reed said. "The technology is not there yet for that application, but our work represents a step closer."
DOE/Lawrence Livermore National Laboratory
Acoustic Waves News and Current Acoustic Waves Events RSSCOROT surprises a year after launch
The space-borne telescope, COROT (Convection, Rotation and planetary Transits), has just completed its first year in orbit. The observatory has brought in surprises after over 300 days of scientific observations.
Light and sound -- the way forward for better medical imaging
Detection and treatment of tumours, diseased blood vessels and other soft-tissue conditions could be significantly improved, thanks to an innovative imaging system being developed that uses both light and sound.
COROT space mission ready to search out new planets and map the interior of stars
The COROT mission is scheduled for launch on the 27th December 2006, from Baikonur in Kazakhstan.
Mountain winds may create atmospheric hotspots
Rapidly fluctuating wind gusts blowing over mountains and hills can create "hotspots" high in the atmosphere and significantly affect regional air temperatures.
Burning asteroids may play 'more important climate role than previously recognized'
Dust from asteroids entering the atmosphere may influence Earth's weather more than previously believed, researchers have found.
Archive Trawl Gives Bison Three Decades Of Solar Music
Scientists in Birmingham have scoured the archives and put together a complete archive of helioseismic data for nearly three solar cycles. The results from reprocessing the data will shed light on the link between helioseismology, the study of sound waves resonating within the Sun, and solar activity. Dr Graham Verner will be presenting preliminary findings at the RAS National Astronomy Meeting at the University of Birmingham on Tuesday 5th April.
Sound Filters Light
Russian researchers have developed a small, smart and tolerant to vibrations spectrometer, which is equally reliable in the outer space and in oceanic depths. The development was performed with financial support from the Russian Foundation for Basic Research (RFBR) and the Foundation for Assistance to Small Innovative Enterprises (FASIE). The unique device is based on a completely new principle: the light goes through an acoustooptical filter in the device.
Astrophysicists Listen to Loops Shivering on the Sun
You would imagine that a 500,000 kilometre long arch of super heated plasma releasing energy equal to the simultaneous explosion of 40 billion Hiroshima atomic bombs would be as easy to "hear" as it is to "see" - but it's not. Astrophysicists have long thought about using the acoustic waves in these flares to understand more about these gigantic events, that can be dozens of times bigger than the Earth, but have been unable to use effectively up till now. Now researchers at the University of Warwick, and Lockheed Martin's Solar and Astrophysics lab in Palo Alto, have found a way to "listen" to how these gigantic loops "shiver" - vastly increasing our abili
Designing latest-generation antennae for communications satellites
For his PhD thesis, the engineer, Jorge Teniente Vallinas, has developed a method for designing antennas used in satellites such as Hispasat. The PhD, at the Public University of Navarre, was awarded the second prize in the latest edition of the Rosina Ribalta Awards from the Epson Ibérica Foundation for the best PhD thesis in the field of Information and Communications Technology. The aims of this doctoral thesis were, on the one hand, to establish the bases for the design of Gaussian profiled corrugated antennae which has been worked on by the Public University of Navarre Antennae Group since 1995 and, on the other, to devise and design cutting edge technology of antennae, reducing
A finite dodecahedral Universe
A franco-american quintet of cosmologists [1] conducted by Jean-Pierre Luminet, from Paris Observatory (LUTH), has proposed an original explanation to account for a surprising detail observed in the Cosmic Microwave Background (CMB) recently mapped by the NASA satellite WMAP. According to the team, who published their study in the 9 october 2003 issue of "Nature", an intriguing discrepancy in the background luminous texture of the Universe can indeed be explained by a very specific global shape of space (its "topology"). The Universe could be wrapped around, a little bit like a "soccer ball", the volume of which would represent only 80% of the observable Universe! According to the leading c
More Acoustic Waves News Articles
 | Designing a Digital Portfolio (VOICES) by Cynthia Baron It isn't easy finding a job these days and for those working in the creative fields like graphic design, illustration, photography, filmmaking, and music, a digital portfolio is just the shiny object you need to catch the attention of a prospective employer. But you can't just slap a few files on a CD and call it a night. As Cynthia Baron points out in Designing a Digital Portfolio--a thorough... |
 | Vibrations and Waves (M.I.T. Introductory Physics Series) by A. P. French |
 | Physics of Sound, The (3rd Edition) by Richard E Berg, David G Stork This book incorporates the developments in digital audio technology, including consumer products, into a firm foundation of the physics of sound. No knowledge of physics, mathematics, or music is required. Includes updated information on musical synthesizers. Provides recent information on the ear, including new advances in cochlear implant technology. Updates material for modern technology,... |
 | RTP: Audio and Video for the Internet (Kaleidoscope) by Colin Perkins |
 | Fundamentals of Acoustics by Lawrence E. Kinsler, Austin R. Frey, Alan B. Coppens, James V. Sanders The classic acoustics reference! This widely-used book offers a clear treatment of the fundamental principles underlying the generation, transmission, and reception of acoustic waves and their application to numerous fields. The authors analyze the various types of vibration of solid bodies and the propagation of sound waves through fluid... |
 | Cymatics: A Study of Wave Phenomena & Vibration by Hans Jenny |
 | Apple Training Series: GarageBand 3 (Apple Training) by Mary Plummer Whether you're an accomplished musician or a student, Garageband is the most rewarding way to create, perform, and record your own music. In the only Apple-certified guide to Garageband, composer and master trainer Mary Plummer shows you just how easy it is to turn your Mac into a fully featured recording studio. Plummer offers a complete, self-paced course in all aspects of Garageband - from... |
 | Fields and Waves in Communication Electronics by Simon Ramo, John R. Whinnery, Theodore Van Duzer This comprehensive revision begins with a review of static electric and magnetic fields, providing a wealth of results useful for static and time-dependent fields problems in which the size of the device is small compared with a wavelength. Some of the static results such as inductance of transmission lines calculations can be used for microwave frequencies. Familiarity with vector operations,... |
 | Darker Than the Deepest Sea: The Search for Nick Drake by Trevor Dann When Nick Drake (1948-1974) died of a drug overdose at twenty-six, he left behind three modest-selling albums, including the stark Pink Moon and the lush Bryter Layter. Three decades later, he is recognized as one of the true geniuses of English acoustic music. Yet Nick Drake--whose music was as gentle and melancholy as the man himself-- has always maintained a spectral presence in popular music.... |
 | Dynamics of the Singing Voice by Meribeth Dayme (geb. Bunch) The book is designed as a reference text for teachers of singing, singers, choral conductors and organists, speech and voice therapists, laryngologists and other health professionals, psychologists and those in linguistics. It discusses the physiological, psychological, musical and emotional aspects of the voice, particularly as they relate to singing but also to speaking. Important features of... |
| © 2008 BrightSurf.com |