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Pitt and Bell Labs researchers send 'heavy photons' over world-record distances
June 22, 2005Unsurpassed exciton distances, lifetimes may lead to new form of optical communication
PITTSBURGH-When light hits a semiconductor material and is absorbed, its photons can become "excitons," sometimes referred to as "heavy photons" because they carry energy, like photons, but have mass, like electrons. Excitons typically exist for only a short time-trillionths of a second-and travel only a few microns before turning back into photons, which are then emitted from the material.
In the June 10 issue of the journal Physical Review Letters, scientists from the University of Pittsburgh and Bell Labs, the R&D arm of Lucent Technologies, report that they have designed and demonstrated a two-dimensional semiconductor structure in which excitons exist longer and travel farther than previously recorded. In their paper, titled "Long-Distance Diffusion of Excitons in Double Quantum Well Structures," David Snoke, senior author and associate professor of physics and astronomy at Pitt, and his colleagues report a system in which excitons move freely over distances of hundreds of microns. Their findings open up the possibility of new applications, such as excitonic circuits.
The researchers "stretched out" the excitons by pulling them apart with an electrical field. This extended the excitons' lifetimes by a million (up to 30 microseconds) and expanded the distances the excitons traveled (up to a millimeter). They were able to "see" the excitons by observing the emitted photons. The semiconductor structures designed in the experiment are of "world-record quality," said Snoke.
The ability to control excitons over long distances could lead to excitonic circuits in which photons are converted directly into excitons, which are then steered around a chip and converted back into photons again at a different location, such as an optical memory device, said Snoke. "It's another tool in our optics toolbox," he said.
"We're doing this with semiconductor circuits now designed for moving electrons," he added. "It's a completely new type of control over the system."
Other authors of the paper are Zoltan Voros and Ryan Balili, graduate students in Pitt's Department of Physics and Astronomy, and Loren Pfeiffer and Kenneth West of Bell Labs.
University of Pittsburgh
The researchers "stretched out" the excitons by pulling them apart with an electrical field. This extended the excitons' lifetimes by a million (up to 30 microseconds) and expanded the distances the excitons traveled (up to a millimeter). They were able to "see" the excitons by observing the emitted photons. The semiconductor structures designed in the experiment are of "world-record quality," said Snoke.
The ability to control excitons over long distances could lead to excitonic circuits in which photons are converted directly into excitons, which are then steered around a chip and converted back into photons again at a different location, such as an optical memory device, said Snoke. "It's another tool in our optics toolbox," he said.
"We're doing this with semiconductor circuits now designed for moving electrons," he added. "It's a completely new type of control over the system."
Other authors of the paper are Zoltan Voros and Ryan Balili, graduate students in Pitt's Department of Physics and Astronomy, and Loren Pfeiffer and Kenneth West of Bell Labs.
University of Pittsburgh
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Excitons in Low-Dimensional Semiconductors: Theory, Numerical Methods, Applications (Springer Series in Solid-State Sciences) by Stephan Glutsch (Author) Low-dimensional semiconductors have become a vital part of today's semiconductor physics, and excitons in these systems are ideal objects that bring textbook quantum mechanics to life. Furthermore, their theoretical understanding is important for experiments and optoelectronic devices. The author develops the effective-mass theory of excitons in low-dimensional semiconductors and describes numerical methods for calculating the optical absorption including Coulomb interaction, geometry, and external fields. The theory is applied to Fano resonances in low-dimensional semiconductors and the Zener breakdown in superlattices. Comparing theoretical results with experiments, the book is essentially self-contained; it is a hands-on approach with detailed derivations, worked examples,... |
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Theory of Excitons by Robert S. Knox (Author) | |
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Photosynthetic Excitons by Herbert Van Amerongen (Author), Leonas Valkunas (Author), Rienk Van Grondelle (Author) Contents include structural organization, spectral properties and excitation energy transfer in photosynthesis, the exciton concept, spectral shapes, spectroscopy of excitons in molecular crystals and aggregates, exciton dynamics, nonlinear annihilation of excitons, and more. |
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Excitons: Their Properties and Uses by Donald C. Reynolds (Author) | |
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Self-Trapped Excitons (Springer Series in Solid-State Sciences) by K. S. Song (Author), R. T. Williams (Author) Self-Trapped Excitons discusses the structure and evolution of the self-trapped exciton (STE) in a wide range of materials. It includes a comprehensive review of experiments and extensive tables of data. Emphasis is given throughout to the unity of the basic physics underlying various manifestations of self-trapping, with the theory being developed from a localized, atomistic perspective. The topics treated in detail in relation to STE relaxation include spontaneous symmetry breaking, lattice defect formation, radiation damage, and electronic sputtering. |
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Bose-Einstein Condensation of Excitons and Biexcitons: And Coherent Nonlinear Optics with Excitons by S. A. Moskalenko (Author), D. W. Snoke (Author) Bose-Einstein condensation of excitons is a unique effect in which the electronic states of a solid can self-organize to acquire quantum phase coherence. The phenomenon is closely linked to Bose-Einstein condensation in other systems such as liquid helium and laser-cooled atomic gases. Covering theoretical aspects as well as recent experimental work, the book provides a comprehensive survey of the field. After introducing the relevant basic physics of excitons, the authors discuss exciton-phonon interactions as well as the behavior of biexcitons. They also cover exciton phase-transitions and give particular attention to nonlinear optical effects including the optical Stark effect and chaos in excitonic systems. The thermodynamics of equilibrium, quasiequilibrium, and nonequilibrium... |
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Excitons in molecular crystals;: Theory and applications (Frontiers in chemistry) by David Parker Craig (Author) | |
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Excitons at high density (Springer tracts in modern physics) by H Haken (Author) | |
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Exciton: Webster's Timeline History, 1957 - 2007 by Icon Group International (Author) Webster's bibliographic and event-based timelines are comprehensive in scope, covering virtually all topics, geographic locations and people. They do so from a linguistic point of view, and in the case of this book, the focus is on "Exciton," including when used in literature (e.g. all authors that might have Exciton in their name). As such, this book represents the largest compilation of timeline events associated with Exciton when it is used in proper noun form. Webster's timelines cover bibliographic citations, patented inventions, as well as non-conventional and alternative meanings which capture ambiguities in usage. These furthermore cover all parts of speech (possessive, institutional usage, geographic usage) and contexts, including pop culture, the arts, social sciences... |
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Optics of Excitons in Confined Systems, Proceedings of the INT Meeting, Italy, 24-27 September 1991 (Institute of Physics Conference Series) by D'Andrea (Author) Optics of Excitons in Confined Systems provides an overview of research in semiconductors that exhibit resonance enhanced optical nonlinearities in the frequency range close to the valence-conduction band gap. The book is divided into the following sections: quantum wells, wires, and dots; superlattices; nonlinear optical properties of confined systems; and effects of external fields on confined systems. Topics range from fundamental theory to more applied aspects of excitons in confined sytems. |
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