 |
|
Single-Crystal Semiconductor Wire Built into an Optical Fiber
March 13, 2008An international science team from Penn State University in the United States and the University of Southampton in the United Kingdom has developed a process for growing a single-crystal semiconductor inside the tunnel of a hollow optical fiber. The device adds new electronic capabilities to optical fibers, whose performance in electronic devices such as computers typically is degraded by the interface between the fiber and the device. The research is important because optical fibers -- which are used in a wide range of technologies that employ light, including telecommunications, medicine, computing, and remote-sensing devices -- are ideal media for transmitting many types of signals.
The development of the single-crystal device, which will be described in a paper to be published later this month in the journal Advanced Materials, builds on research reported in 2006, in which the team first combined optical fibers with polycrystalline and amorphous semiconductor materials in order to create an optical fiber that also has electronic characteristics. The group's latest finding -- that a single-crystal semiconductor also can be integrated into an optical fiber -- is expected to lead to even further improvements in the characteristics of optical fibers used in many areas of science and technology.
"For most applications, single-crystal semiconductor materials have better performance than polycrystalline and amorphous materials," said John Badding, associate professor of chemistry at Penn State. "We have now shown that our technique of encasing a single-crystal semiconductor within an optical fiber results in greater functionality of the optical fiber, as well."
The team used a high-pressure fluid-liquid-solid approach to build the crystal inside the fiber. First, the scientists deposited a tiny plug of gold inside the fiber by exposing a gold compound to laser light. Next, they introduced silane, a compound of silicon and hydrogen, in a stream of high-pressure helium. When the fiber was heated, the gold acted as a catalyst, decomposing the silane and thus allowing silicon to deposit as a single crystal behind the moving gold catalyst particle, forming a single-crystal wire inside the fiber.
"The key to joining two technologies lies not only in the materials, but also in how the functions are built in," said Pier Sazio, senior research fellow in the Optoelectronics Research Centre at the University of Southampton. "We were able to embed a nanostructured crystal into the hollow tube of an optical fiber to create a completely new type of composite device."
The research team sees potential to carry the application to the next level. "At present, we still have electrical switches at both ends of the optical fiber," said Badding. "If we can get to the point where the electrical signal never leaves the fiber, it will be faster and more efficient."
The research received financial support from the U. S. National Science Foundation, the Penn State Center for Nanoscale Science, and the Penn State-Lehigh Center for Optical Technologies.
Penn State University
The team used a high-pressure fluid-liquid-solid approach to build the crystal inside the fiber. First, the scientists deposited a tiny plug of gold inside the fiber by exposing a gold compound to laser light. Next, they introduced silane, a compound of silicon and hydrogen, in a stream of high-pressure helium. When the fiber was heated, the gold acted as a catalyst, decomposing the silane and thus allowing silicon to deposit as a single crystal behind the moving gold catalyst particle, forming a single-crystal wire inside the fiber.
"The key to joining two technologies lies not only in the materials, but also in how the functions are built in," said Pier Sazio, senior research fellow in the Optoelectronics Research Centre at the University of Southampton. "We were able to embed a nanostructured crystal into the hollow tube of an optical fiber to create a completely new type of composite device."
The research team sees potential to carry the application to the next level. "At present, we still have electrical switches at both ends of the optical fiber," said Badding. "If we can get to the point where the electrical signal never leaves the fiber, it will be faster and more efficient."
The research received financial support from the U. S. National Science Foundation, the Penn State Center for Nanoscale Science, and the Penn State-Lehigh Center for Optical Technologies.
Penn State University
Optical Fiber Current Events and Optical Fiber News RSSPushing light beyond its known limits
Scientists at the University of Adelaide have made a breakthrough that could change the world's thinking on what light is capable of.
Making monster waves
Rogue waves-giant waves that spring up suddenly and tower over the seas around them-have inspired physicists to look for an analogue in light.
New NIST method reveals all you need to know about 'waveforms'
The National Institute of Standards and Technology (NIST) has unveiled a method for calibrating entire waveforms-graphical shapes showing how electrical signals vary over time-rather than just parts of waveforms as is current practice.
New multi-use device can shed light on oxygen intake
A fiber-optic sensor created by a team of Purdue University researchers that is capable of measuring oxygen intake rates could have broad applications ranging from plant root development to assessing the effectiveness of chemotherapy drugs.
Penetrating insights: NIST airframe tests help ensure better shielding for flight instruments
Airline travelers are used to being instructed to turn off computers and cell phones during takeoffs and landings as a precaution against interfering with the plane's navigational equipment, but outside sources of high-energy interference can be even more dangerous.
NIST develops novel ion trap for sensing force and light
Miniature devices for trapping ions (electrically charged atoms) are common components in atomic clocks and quantum computing research. Now, a novel ion trap geometry demonstrated at the National Institute of Standards and Technology (NIST) could usher in a new generation of applications because the device holds promise as a stylus for sensing very small forces or as an interface for efficient transfer of individual light particles for quantum communications.
MIT: Making waves in the brain
Scientists have studied high-frequency brain waves, known as gamma oscillations, for more than 50 years, believing them crucial to consciousness, attention, learning and memory.
Shedding some light on Parkinson's treatment
A research team lead by Karl Deisseroth in the bioengineering department at Stanford University has developed a technique to systematically characterize disease circuits in the brain.
Spreading high-speed Internet to rural areas
To cut the cost of bringing high-speed Internet to rural areas, Dr. Ka Lun Lee and colleagues at the University of Melbourne and NEC Australia in the state of Victoria are experimenting with a way to boost the reach of existing technology.
Engineers ride 'rogue' laser waves to build better light sources
A freak wave at sea is a terrifying sight. Seven stories tall, wildly unpredictable, and incredibly destructive, such waves have been known to emerge from calm waters and swallow ships whole.
More Optical Fiber Current Events and Optical Fiber News Articles
 |
Fundamentals of Optical Fibers (Wiley Series in Pure and Applied Optics) by John A. Buck (Author) An introduction to the operating principles of optical fiber Substantially rewritten, Fundamentals of Optical Fibers, Second Edition offers readers a timely and consistent introduction to the fundamental principles of light propagation in fibers. Incorporating the many developments in the field since the first edition appeared in 1995, this new edition reviews, in-depth, fundamental waveguiding principles, the influence of various fiber structures and materials on light transmission, and nonlinear propagation effects. Since the main applications of optical fibers occur within communication systems, the focus throughout is on topics that pertain to that domain. Equally useful to professionals seeking an in-depth reference and as a text for senior- and graduate-level students,... |
 |
Cables To Go 98038 Premium Toslink Optical Digital Audio Cable (8 Feet, Black/Grey) by Cables To Go This Premium Toslink Digital Optical cable from Cables To Go is manufactured from high-quality PMMA optical fiber with a polished lens and gold-plated collet to provide an accurate digital signal. The stylish and durable PVC jacket adds flexibility and durability for years of listening pleasure. Optical cables transfer the signal using light; thus completely eliminating any chance for RFI, EMI or ground loop interference. Connect your DVD, CD, Satellite Receiver, Game console or other digital audio equipment for clear, full detailed sound. |
 |
Mediabridge - Toslink Cable - Optical Digital Audio Cable - 6ft by Mediabridge Products, LLC. Toslink Optical Digital Audio patch cords provide High Grade Multichannel Digital Audio. Most Recent Converters such as; DVD/Blu-Ray players & Dolby Digital/DTS Surround Sound Receivers offer the Toslink Interface. |
 |
Optical Fiber Communications: Principles and Practice (3rd Edition) by John Senior (Author) Senior is an established core text in a field that is growing fast, and in which technology is constantly evolving. The text succeeds in giving a practical introduction to the fundamentals, problems and techniques of design and utilisation of optical fiber systems. It is respected as the most comprehensive and practical book in the market. This new edition will retain all core features, while incorporating recent improvements and developments in the field. Optical fiber systems have now become more sophisticated and, as a result, are now the communication method of choice for many systems. New/additional material will include optical amplifiers, soliton systems and optical networks. |
 |
2PCS 12ft Digital Audio Optical Fiber Toslink Cable by Eforcity Eforcity Branded Accessory. Enjoy 30-Days Money Back Guarantee if purchased through Eforcity. |
 |
Optical Fiber Communications with CD-ROM by Gerd Keiser (Author), Gerd Keiser (Author) The third edition of this popular text and reference book presents the fundamental principles for understanding and applying optical fiber technology to sophisticated modern telecommunication systems. Optical-fiber-based telecommunication networks have become a major information-transmission-system, with high capacity links encircling the globe in both terrestrial and undersea installations. Numerous passive and active optical devices within these links perform complex transmission and networking functions in the optical domain, such as signal amplification, restoration, routing, and switching. Along with the need to understand the functions of these devices comes the necessity to measure both component and network performance, and to model and stimulate the complex behavior of... |
 |
Acoustic Research PR181 Fiber Optical/Toslink Digital Cable (6 feet) by Acoustic Research Precision-made fiber optic cable is engineered for high-capacity signal delivery to digital audio/video systems for crystal clear sound.PRODUCT FEATURES:Highly-polished, convex lens precisely focuses light for accurate digital signal transfer for true sound reproduction;24K gold-plated collar protects lens from damage;Heavy-duty strain relief and large diameter outer jacket help prevent kinking and maintains digital signal integrity;Proprietary design rubber/metal grip: easy, non-slip installation and removal;Internal cladding over optical fiber: lower refractive index, preserves fiber strength for maximum light transfer;High grade digital audio optical fiber meets high speed signal demands of digital audio components. |
 |
Mini Fiber Optic Light by Westminster Enhance the romance with the elegance of fiber optic lighting -- Turn off the lights and see floating blue dots shining in the air. Fiber Optic lighting is the technology of transmitting light from a centralized source (illuminator) through and acrylic cable (stranded or solid core) to a feature or fixture. -- This classic Fiber Optic Light is great for a table topper at parties or anywhere in the house. 12 hours battery life. Silver base. Measures 9" tall. -- Requires 3 AA batteries (not included), can also run off a 4.5V power adapter (not included). |
 |
Monster MPC ILS400C-3M Toslink Fiber Optic Audio Cable (3 meters) by Monster Enjoy Ultimate Quality Digital Audio with Pinpoint Accuracy for an Unparalleled Mobile Entertainment Experience. Getting clean, detailed sound reproduction from your high-end mobile entertainment system often requires using a digital fiber optic cable to connect your processors and multimedia components. Inferior digital cable construction can cause signal loss, jitter and overall poor performance. Monster 400 Series Fiber Optic Digital Audio Interconnects feature advanced technologies including high-grade, specially tuned optical fibers and precision polished fiber terminations that reduce jitter and maximize sonic clarity. Your digital processor, DVD player and gaming system with digital outputs will jump to life with remarkable realism, dynamics and clarity. |
 |
12 FT Digital Audio Optical TOSLink Cable Optic 12ft by Abacus24-7 Optical Digital Interface Cable provides superior accuracy for signal transfer of digital information from component to component. This cable is an excellent complement to your component entertainment system. Better definition and true clarity. It is specifically engineered for a digital signal data transfer. For highest quality signal transfer in digital components using Toslink optical to Toslink optical connections. The optical signal offers more digital information at higher speed and only a cable manufactured with glass fiber will provide this extra data. Because the information is converted into light impulses that are sent over the fiber optic cable, the signal is immune from RF or magnetic interference. Fiber optic Toslink connections are used on high-end stereo equipment and... |
| © 2009 BrightSurf.com |