العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
EspañolBALLISTIC TRANSPORT
In solid state physics, the term 'ballistic transport' 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.
In general the resistivity exists because an electron, while moving inside a medium, is scattered by impurities, defects, or by the atoms/molecules composing the medium that simply oscillate around their equilibrium position (in a solid), or generically by any freely moving atom/molecule composing the medium, in a gas or liquid.
For a given medium one can associate to a moving electron a mean free path as the average length that the electron can travel freely, i.e. before ''hitting'' against something and deviating from its original path, possibly losing some kinetic energy. The mean free path can be increased by reducing the number of impurities in a crystal or by lowering its temperature (except for some material like semi-conductors).
Ballistic transport is observed when the mean free path of the electron is (much) bigger than the size of the ''box'' that contains/delimits the medium through which the electron travels, such that the electron alters its motion only by hitting against the ''walls''.
In the case of a wire supended in air/vacuum the surface of the wire plays the role of the ''box'' reflecting the electrons and preventing them from exiting toward the empty space/open air. This is due to the fact that there is an energy to be paid to extract the electron from the medium (extraction potential).
E.g. ballistic transport can be observed in a metal nanowire: this is simply due to the fact that the wire is of the size of a nanometer ( meters) and the mean free path can be bigger than that in a metal [1]
Quasi-ballistic transport can be observed in a semiconductor, for example, in modern MOS transistors. Professor Mark Lundstrom of Purdue University has published a lot on quasi-ballistic transport theory in modern MOS transistors. Lundstrom's theory explains why the low-field mobility is important even at high electric field [1]-[2]. This is contradictory to the conventional theory that at high electric field the saturation velocity is important while the low field mobility is not important. This concept is important for strain engineering because strain engineering can be used to increase low-field mobility, which can make carrier transport faster even at high electric field according to Lundstrom's theory.
[1] M.S. Lundstrom, “Elementary Scattering Theory of the Si MOSFET”, IEEE Electron Dev. Lett., vol 18, pp. 361-363 (1997).
[2] M.S. Lundstrom, “On the Mobility Versus Drain Current Relation for a Nanoscale MOSFET”, IEEE Electron Dev. Lett., vol. 22, pp. 293-295 (2001).
In general the resistivity exists because an electron, while moving inside a medium, is scattered by impurities, defects, or by the atoms/molecules composing the medium that simply oscillate around their equilibrium position (in a solid), or generically by any freely moving atom/molecule composing the medium, in a gas or liquid.
For a given medium one can associate to a moving electron a mean free path as the average length that the electron can travel freely, i.e. before ''hitting'' against something and deviating from its original path, possibly losing some kinetic energy. The mean free path can be increased by reducing the number of impurities in a crystal or by lowering its temperature (except for some material like semi-conductors).
Ballistic transport is observed when the mean free path of the electron is (much) bigger than the size of the ''box'' that contains/delimits the medium through which the electron travels, such that the electron alters its motion only by hitting against the ''walls''.
In the case of a wire supended in air/vacuum the surface of the wire plays the role of the ''box'' reflecting the electrons and preventing them from exiting toward the empty space/open air. This is due to the fact that there is an energy to be paid to extract the electron from the medium (extraction potential).
E.g. ballistic transport can be observed in a metal nanowire: this is simply due to the fact that the wire is of the size of a nanometer ( meters) and the mean free path can be bigger than that in a metal [1]
Quasi-ballistic transport can be observed in a semiconductor, for example, in modern MOS transistors. Professor Mark Lundstrom of Purdue University has published a lot on quasi-ballistic transport theory in modern MOS transistors. Lundstrom's theory explains why the low-field mobility is important even at high electric field [1]-[2]. This is contradictory to the conventional theory that at high electric field the saturation velocity is important while the low field mobility is not important. This concept is important for strain engineering because strain engineering can be used to increase low-field mobility, which can make carrier transport faster even at high electric field according to Lundstrom's theory.
[1] M.S. Lundstrom, “Elementary Scattering Theory of the Si MOSFET”, IEEE Electron Dev. Lett., vol 18, pp. 361-363 (1997).
[2] M.S. Lundstrom, “On the Mobility Versus Drain Current Relation for a Nanoscale MOSFET”, IEEE Electron Dev. Lett., vol. 22, pp. 293-295 (2001).
This article provided by Wikipedia. To edit the contents of this article, click here for original source.
psst.. try this: add to faves
