Thermoelectric power in nanostructured materials : strong magnetic fields
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Bibliographic Information
Thermoelectric power in nanostructured materials : strong magnetic fields
(Springer series in materials science, 137)
Springer, c2010
- hbk.
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The Institute for Solid State Physics Library. The University of Tokyo.図書室
hbk.428.4:T267210315128
Note
Includes bibliographical references and index
Description and Table of Contents
Description
The merging of the concept of introduction of asymmetry of the wave vector space of the charge carriers in semiconductors with the modern techniques of fabric- ing nanostructured materials such as MBE, MOCVD, and FLL in one, two, and three dimensions (such as ultrathin ?lms, nipi structures, inversion and accumu- tion layers, quantum well superlattices, carbon nanotubes, quantum wires, quantum wire superlattices, quantumdots, magnetoinversionand accumulationlayers, qu- tum dot superlattices, etc. ) spawns not only useful quantum effect devices but also unearth new concepts in the realm of nanostructured materials science and related disciplines. It is worth remaking that these semiconductor nanostructures occupy a paramount position in the entire arena of low-dimensional science and technology by their own right and ?nd extensive applications in quantum registers, resonant tunneling diodes and transistors, quantum switches, quantum sensors, quantum logic gates, heterojunction ?eld-effect, quantum well and quantum wire trans- tors, high-speed digital networks, high-frequency microwave circuits, quantum cascade lasers, high-resolution terahertz spectroscopy, superlattice photo-oscillator, advanced integrated circuits, superlattice photocathodes, thermoelectric devices, superlattice coolers, thin ?
lm transistors, intermediate-band solar cells, micro- tical systems, high-performanceinfrared imaging systems, bandpass ?lters, thermal sensors, optical modulators, optical switching systems, single electron/molecule electronics, nanotube based diodes, and other nanoelectronic devices.
Table of Contents
Thermoelectric power under large magnetic field in quantum confined materials.- Thermoelectric Power in Quantum Dots Under Large Magnetic Field.- Thermoelectric Power in Ultrathin Films and Quantum Wires Under Large Magnetic Field.- Thermoelectric Power in Quantum Dot Superlattices Under Large Magnetic Field.- Thermoelectric Power in Quantum Wire Superlattices Under Large Magnetic Field.- Thermoelectric power under magnetic quantization in macro and micro electronic materials.- Thermoelectric Power in Macroelectronic Materials Under Magnetic Quantization.- Thermoelectric Power in Superlattices Under Magnetic Quantization.- Thermoelectric Power in Ultrathin Films Under Magnetic Quantization.- Thermoelectric power under large magnetic field in quantum confined optoelectronic materials in the presence of light waves.- Optothermoelectric Power in Ultrathin Films and Quantum Wires of Optoelectronic Materials Under Large Magnetic Field.- Optothermoelectric Power in Quantum Dots of Optoelectronic Materials Under Large Magnetic Field.- Optothermoelectric Power in Quantum-Confined Semiconductor Superlattices of Optoelectronic Materials Under Large Magnetic Field.- Thermoelectric power under magnetic quantization in macro and micro optoelectronic materials in the presence of light waves.- Optothermoelectric Power in Macro-Optoelectronic Materials Under Magnetic Quantization.- Optothermoelectric Power in Ultrathin Films of Optoelectronic Materials Under Magnetic Quantization.- Optothermoelectric Power in Superlattices of Optoelectronic Materials Under Magnetic Quantization.- Applications and Brief Review of Experimental Results.- Conclusion and Future Research.
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