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A nanowire is a wire of dimensions of the order of a nanometer (10−9 meters). At these scales, quantum mechanical effects are important - hence such wires are also known as "quantum wires". Many different types of nanowires exist, ranging from metallic (e.g. Ni, Pt, Au) to semiconducting (e.g. InP, Si, GaN, etc.) and insulating (e.g. SiO2,TiO2). Molecular nanowires are composed of repeating molecular units either organic (e.g. DNA) or inorganic (e.g. Mo6S9-xIx). In material science, a Quantum wire is an electically conducting wire, in which quantum transport effects are important. ...
The nanowires could be used, in a near feature, as components of nanotechnology to create electrical circuits out of compounds that are capable of being formed into extremely small circuits. In general, a things components are its parts; the things that compose it. ...
A mite next to a gear set produced using MEMS, the precursor to nanotechnology. ...
An electrical network or electrical circuit is an interconnection of electrical elements such as resistors, inductors, capacitors, diodes, switches and transistors. ...
A compound is an area of land that is surrounded by fences, walls, or barbed wire and is used for a particular purpose, especially an area containing buildings and where the entry and exit of people is controlled. ...
An electrical network or electrical circuit is an interconnection of electrical elements such as resistors, inductors, capacitors, diodes, switches and transistors. ...
Physics of nanowires Production of nanowires Nanowire are not observed spontaneously in nature and must be produced in a laboratory. Nanowires can be either suspended, deposited or synthesized from the elements. A suspended nanowire is a wire in vacuum chamber held at the extremities. A deposited nanowire is a wire deposited on a surface of different nature: e.g. it could even be a single strip of metallic atoms over a non-conducting surface. A suspended nanowire can be produced by chemical etching of a bigger wire, or bombarding a bigger wire with some highly energetic particles (atoms or molecules). Another way to produce a suspended nanowire is to indent the tip of an STM in the surface, of a metal near the melting point, and retract it. This can form a wire very much like the tip of a fork does with the cheese of a pizza. STM can mean: Scanning tunneling microscope Software transactional memory, a method of handling concurrency in multithreaded systems Synchronous Transport Module, used as a Frame Format in SDH Savings, taxation and imports in economics Société de transport de Montréal Sunday Times Magazine St Thomas More College In publishing, STM publishing means...
A common technique for creating a nanowire is the Vapor-Liquid-Solid (VLS) synthesis method. This technique uses as source material either laser ablated particles or a feed gas (such as silane). The source is then exposed to a catalyst. For nanowires, the best catalysts are liquid metal (such as gold) nanoclusters, which can either be purchased in colloidal form and deposited on a substrate or self-assembled from a thin film by dewetting. This process can often produce crystalline nanowires in the case of semiconductor materials. Silane is a chemical compound with chemical formula SiH4. ...
It has been suggested that Gold bar be merged into this article or section. ...
The source enters these nanoclusters and begins to saturate it. Once supersaturation is reached, the source solidifies and grows outward from the nanocluster. The final product's length can be adjusted by simply turning off the source. Compound nanowires with super-lattices of alternating materials can be created by switching sources while still in the growth phase. Conductivity of nanowires The conductivity of a nanowire can be studied suspending it between two electrodes. Nanowires show peculiar electrical properties due to their size. Unlike carbon nanotubes, whose motion of electrons can fall under the regime of ballistic transport (meaning the electrons can travel freely from one electrode to the other), nanowire conductivity is strongly influenced by edge effects. The edge effects come from atoms that lay at the nanowire surface and are not fully bonded to neighboring atoms like the atoms within the bulk of the nanowire. The unbonded atoms are often a source of defects within the nanowire, and may cause the nanowire to conduct electricity more poorly than the bulk material. As a nanowire shrinks in size, the surface atoms becomes more numerous compared to the atoms within the nanowire, and edge effects become more important. In solid state physics, the term ballistic tranport refers to the transport of electrons in a medium where the electrical resistivity due to the scattering, by the atoms, molecules or impurities in the medium itself, is negligible or absent. ...
Furthermore the conductivity can undergo a quantization in energy: i.e. the energy of the electrons going through a nanowire can assume only discrete values, multiple of the Landauer constant G = 2e2 / h (where e is the charge of the electron and h is Planck's constant). The conductivity is hence described as the sum of the transport by separate channels of different quantized energy levels. The thinner the wire is, the smaller the number of channels available to the transport of electrons. This has been proven by measuring the conductivity of a nanowire while pulling it: while it shrinks, its conductivity decreases in a stepwise fashion and the plateaus correspond to multiples of G. Structure of nanowires The nanowires can show peculiar shapes. Sometimes they can show noncrystalline order, assuming e.g. a pentagonal symmetry or a helicoidal (spiral) shape. The lack of crystalline order is due to the fact that a nanowire is periodic only in one dimension (along its axis). Hence it can assume any order in the other directions (in plane) if this is energetically favorable. E.g., in some cases nanowires can show a fivefold symmetry, usually not observed in nature, but for clusters of few atoms. The fivefold symmetry is equivalent to the icosahedral symmetry of (small) atomic clusters: the icosahedron is often an energetically favorable shape for cluster of few atoms, but icosahedral ordering is not observed in crystals since it is not possible to stack together icosahedra (repeating infinite copies of them in each direction) and tile the whole space (fill it without holes). The term cluster refers to the grouping together of elements within a domain - usually spatial. ...
The term cluster refers to the grouping together of elements within a domain - usually spatial. ...
An icosahedron [ËŒaıkÉ™sÉ™hiËdrÉ™n] noun (plural: -drons, -dra [-drÉ™]) is a polyhedron having 20 faces, but usually a regular icosahedron is meant. ...
Use of nanowires Nanowires still belong to the experimental world of laboratories. However, some early experiments have shown how they can be used to build the next generation of computing devices. To create active electronic elements, the first key step was to chemically dope a semiconductor nanowire. This has already been done to individual nanowires to create p-type and n-type semiconductors. The next step was to find a way to create a p-n junction, one of the simplest electronic devices. This was achieved in two ways. The first way was to physically cross a p-type wire over an n-type wire. The second method involved chemically doping a single wire with different dopants along the length. This method created a p-n junction with only one wire. After p-n junctions were built with nanowires, the next logical step was to build logic gates. By putting connecting several p-n junctions together, researchers have been able to create the basis of all logic circuits: the AND, OR, and NOT gates have all been built from semiconductor nanowire crossings. It's possible that semiconductor nanowire crossings will be important to the future of digital computing. Though there are other uses for nanowires beyond these, the only ones that actually take advantage of physics in the nanometer regime are electronic. References - R. Landauer, J. Phys.: Cond. Matter 1, 8099 (1989) [1]
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