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Encyclopedia > Complementarity

Complementarity is a concept in a number of fields:


Economics

In economics is a concept similar to that of externality. Two goods are complements if their cross elasticity of demand is negative. That is, as the price of one good increases, the demand to the other good decreases. When a large number of complementary products are interconnected, network externalities can arise. In general, complementarity exists when the decisions of other economic agents changes how I value things.


A good example of a complementarity is the example of keyboards. Virtually all keyboards use the QWERTY style, which was created so that typewriters wouldn't jam. Other styles include that promoted by Dvorak. Because QWERTY keyboards are so popular, an individual values it more than the one proposed by Dvorak, even though there is no reason to believe QWERTY to be inherently superior.


See also: network externality, cross elasticity of demand, list of economics topics


Physics

In Physics, "complementarity" is a basic principle of quantum theory, and refers to effects such as the wave-particle duality, in which different measurements made on a system reveal it to have either particle-like or wave-like properties. Niels Bohr is usually associated with this concept; in the orthodox form, it is stated that a quantum mechanical system consisting of a boson or fermion can either behave as a particle or as wave, but never simultaneously as both. A less orthodox interpretation is the "duality condition," described by the inequality due to Englert (see Phys. Rev. Lett., Vol. 77, 2154 (1996)), which allows wave and particle attributes to co-exist, but postulates that a stronger manifestation of the particle nature leads to a weaker manifestation of the wave nature and vice versa.


The emergence of complementarity in a system occurs when one considers the circumstances under which one attempts to measure its properties; as Bohr noted, the principle of complementarity "implies the impossibility of any sharp separation between the behaviour of atomic objects and the interaction with the measuring instruments which serve to define the conditions under which the phenomena appear." It is important to distinguish, as did Bohr in his original statements, the principle of complementarity from a statement of the uncertainty principle. For a technical discussion of contemporary issues surrounding complementarity in physics, see, e.g., [1] (http://citebase.eprints.org/cgi-bin/citations?id=oai:arXiv.org:quant-ph/0003073) (from which parts of this discussion were drawn.)


The Afshar experiment is claimed to question the validity of the principle of complementarity in quantum mechanics.


  Results from FactBites:
 
Complementarity, Bell’s Theorem, and the Framework of Process Metaphysics (6408 words)
Since complementarity is generally read as a way of "explaining" either the indeterminacy relations or wave-particle dualism, it is not widely understood that Bohr arrived at his position essentially through an analysis of classical physics.
Indeed, Bohr argues that the complementarity of particle and wave "pictures" is a consequence of the fact that observation must be theoretically represented as an interaction in which one of the interacting physical systems is understood to be the real object which quantum theory attempts to describe.
From the viewpoint of complementarity, the negative outcome of experiments testing Bell’s inequality is a victory that could have been expected because the arguments from which the inequality is derived commit the very same fallacies that Whitehead named in his critique of the classical framework.
Complementarity (physics) - Wikipedia, the free encyclopedia (507 words)
In physics, complementarity is a basic principle of quantum theory closely identified with the Copenhagen interpretation, and refers to effects such as the wave-particle duality, in which different measurements made on a system reveal it to have either particle-like or wave-like properties.
Complementarity or wave-particle duality is considered to be one of the distinguishing characteristics of quantum mechanics, whose theoretical and experimental development has been honoured by more than a few Nobel Prizes for Physics.
Demonstrates that complementarity is enforced, and quantum interference effects destroyed, by decoherence (irreversible object-apparatus correlations), and not, as was previously popularly believed, by Heisenberg's uncertainty principle itself.
  More results at FactBites »


 
 

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