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Instead an exact calculation of the transverse energies of the confined electrons has to be performed to calculate the wire resistance. Following from the quantization of electron energy, the resistance is also found to be quantized. The importance of the quantization is inversely proportional to the diameter of the nanowire for a given material. From material to material, it is dependent on the electronic properties, especially on the Effective Mass of the electrons. In simple words, it means that it will depend on how conduction electrons interact with the atoms within a given material. In practice, semiconductors show clear conductance quantization for large wire transverse dimensions (100 nm) because the electronic modes due to confinement are spatially extended. As a result their fermi wawelengths are large and thus they have low energy separations. This means that they can only be resolved at cryogenic temperature (few kelvins) where the thermal excitation energy is lower than the inter-mode energy separation. For metals, quantization corresponding to the lowest energy states is only observed for atomic wires. Their corresponding wavelength being thus extremely small they have a very large energy separation which makes resistance quantization perfectly observable at room temperature. CARBON NANOTUBES AS QUANTUM WIRES It is possible to make quantum wires out of Metallic Carbon Nanotube s, at least in limited quantities. The advantages of making wires from carbon nantubes include their high electrical Conductivity – (due to a high Mobility – light weight, Small Scale and tensile strength. The major drawback (as of 2005 ) is cost. It has been claimed that it is possible to create macroscopic quantum wires. With a rope of carbon nanotubes, it is not necessary for any single fiber to travel the entire length, since Quantum Tunneling will allow Electron s to jump from strand to strand. This makes quantum wires interesting for commercial uses. In April 2005, NASA invested $11 million over four years with Rice University to develop the ( Quantum Wire ) with 10 times better conductivity than Copper at one-sixth the weight. It would be made with Carbon Nanotubes and would help reduce the weight of the next generation Shuttle ; but can have wide ranging applications. EXTERNAL LINKS |
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