Physics:Mesoscopic physics

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Short description: Subdiscipline of condensed matter physics that deals with materials of an intermediate size

Mesoscopic physics is a subdiscipline of condensed matter physics that deals with materials of an intermediate size. These materials range in size between the nanoscale for a quantity of atoms (such as a molecule) and of materials measuring micrometres.[1] The lower limit can also be defined as being the size of individual atoms. At the microscopic scale are bulk materials. Both mesoscopic and macroscopic objects contain many atoms. Whereas average properties derived from constituent materials describe macroscopic objects, as they usually obey the laws of classical mechanics, a mesoscopic object, by contrast, is affected by thermal fluctuations around the average, and its electronic behavior may require modeling at the level of quantum mechanics.[2][3]

A macroscopic electronic device, when scaled down to a meso-size, starts revealing quantum mechanical properties. For example, at the macroscopic level the conductance of a wire increases continuously with its diameter. However, at the mesoscopic level, the wire's conductance is quantized: the increases occur in discrete, or individual, whole steps. During research, mesoscopic devices are constructed, measured and observed experimentally and theoretically in order to advance understanding of the physics of insulators, semiconductors, metals, and superconductors. The applied science of mesoscopic physics deals with the potential of building nanodevices.

Mesoscopic physics also addresses fundamental practical problems which occur when a macroscopic object is miniaturized, as with the miniaturization of transistors in semiconductor electronics. The mechanical, chemical, and electronic properties of materials change as their size approaches the nanoscale, where the percentage of atoms at the surface of the material becomes significant. For bulk materials larger than one micrometre, the percentage of atoms at the surface is insignificant in relation to the number of atoms in the entire material. The subdiscipline has dealt primarily with artificial structures of metal or semiconducting material which have been fabricated by the techniques employed for producing microelectronic circuits.[2][3]

There is no rigid definition for mesoscopic physics but the systems studied are normally in the range of 100 nm (the size of a typical virus) to 1 000 nm (the size of a typical bacterium): 100 nanometers is the approximate upper limit for a nanoparticle. Thus, mesoscopic physics has a close connection to the fields of nanofabrication and nanotechnology. Devices used in nanotechnology are examples of mesoscopic systems. Three categories of new electronic phenomena in such systems are interference effects, quantum confinement effects and charging effects.[2][3]

Quantum confinement effects

Quantum confinement effects describe electrons in terms of energy levels, potential wells, valence bands, conduction bands, and electron energy band gaps.

Electrons in bulk dielectric materials (larger than 10 nm) can be described by energy bands or electron energy levels. Electrons exist at different energy levels or bands. In bulk materials these energy levels are described as continuous because the difference in energy is negligible. As electrons stabilize at various energy levels, most vibrate in valence bands below a forbidden energy level, named the band gap. This region is an energy range in which no electron states exist. A smaller amount have energy levels above the forbidden gap, and this is the conduction band.

The quantum confinement effect can be observed once the diameter of the particle is of the same magnitude as the wavelength of the electron's wave function.[4] When materials are this small, their electronic and optical properties deviate substantially from those of bulk materials.[5] As the material is miniaturized towards nano-scale the confining dimension naturally decreases. The characteristics are no longer averaged by bulk, and hence continuous, but are at the level of quanta and thus discrete. In other words, the energy spectrum becomes discrete, measured as quanta, rather than continuous as in bulk materials. As a result, the bandgap asserts itself: there is a small and finite separation between energy levels. This situation of discrete energy levels is called quantum confinement.

In addition, quantum confinement effects consist of isolated islands of electrons that may be formed at the patterned interface between two different semiconducting materials. The electrons typically are confined to disk-shaped regions termed quantum dots. The confinement of the electrons in these systems changes their interaction with electromagnetic radiation significantly, as noted above.[6][7]

Because the electron energy levels of quantum dots are discrete rather than continuous, the addition or subtraction of just a few atoms to the quantum dot has the effect of altering the boundaries of the bandgap. Changing the geometry of the surface of the quantum dot also changes the bandgap energy, owing again to the small size of the dot, and the effects of quantum confinement.[6]

Interference effects

In the mesoscopic regime, scattering from defects – such as impurities – induces interference effects which modulate the flow of electrons. The experimental signature of mesoscopic interference effects is the appearance of reproducible fluctuations in physical quantities. For example, the conductance of a given specimen oscillates in an apparently random manner as a function of fluctuations in experimental parameters. However, the same pattern may be retraced if the experimental parameters are cycled back to their original values; in fact, the patterns observed are reproducible over a period of days. These are known as universal conductance fluctuations.

Time-resolved mesoscopic dynamics

Time-resolved experiments in mesoscopic dynamics: the observation and study, at nanoscales, of condensed phase dynamics such as crack formation in solids, phase separation, and rapid fluctuations in the liquid state or in biologically relevant environments; and the observation and study, at nanoscales, of the ultrafast dynamics of non-crystalline materials.[8][9]



  1. Muller, M.; Katsov, K.; Schick, M. (November 2006). "Biological and synthetic membranes: What can be learned from a coarse-grained description?". Physics Reports 434 (5–6): 113–176. doi:10.1016/j.physrep.2006.08.003. ISSN 0370-1573. Bibcode2006PhR...434..113M. 
  2. 2.0 2.1 2.2 "Sci-Tech Dictionary". McGraw-Hill Dictionary of Scientific and Technical Terms. McGraw-Hill Companies, Inc.. 2003. 
  3. 3.0 3.1 3.2 "Mesoscopic physics." McGraw-Hill Encyclopedia of Science and Technology. The McGraw-Hill Companies, Inc., 2005. 25 Jan 2010.
  4. Cahay, M (2001). Quantum confinement VI : nanostructured materials and devices : proceedings of the international symposium. Cahay, M., Electrochemical Society.. Pennington, N.J.: Electrochemical Society. ISBN 978-1566773522. OCLC 49051457. 
  5. Hartmut, Haug; Koch, Stephan W. (1994). Quantum theory of the optical and electronic properties of semiconductors (3rd ed.). Singapore: World Scientific. ISBN 978-9810220020. OCLC 32264947. 
  6. 6.0 6.1 Quantum dots . 2008 Evident Technologies, Inc.
  7. Sánchez D, Büttiker M (2004). "Magnetic-field asymmetry of nonlinear mesoscopic transport". Phys. Rev. Lett. 93 (10): 106802. doi:10.1103/PhysRevLett.93.106802. PMID 15447435. Bibcode2004PhRvL..93j6802S. 
  8. Barty, Anton (2008-06-22). "Ultrafast single-shot diffraction imaging of nanoscale dynamics". Nature Photonics 2 (7): 415–419 (2008). doi:10.1038/nphoton.2008.128. 
  9. "Study gains images at ultra-fast timescale" (The research appears in the online edition of the journal Nature Photonics). Science Online. Facts On File, Inc (United Press International): pp. 01. 2008-06-25. 

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