Difference between revisions of "Applying the Uncertainty Principle to Single Particle Interactions"
(Imported from text file) |
(Imported from text file) |
||
Line 15: | Line 15: | ||
==Abstract== | ==Abstract== | ||
− | Existing derivations of uncertainty for single particle interactions violate complementarity because they require that the photon exhibit wave and particle behavior simultaneously; and thus singularly. In order to restore physical consistency to quantum theory a model of the photon is proposed having spatial extension equal to the wavelength. As a result uncertainty and indeterminacy must be assigned independent meanings. Uncertainty describes the limit in measurability for instantaneous exchanges of momentum and is due to a photon's particle properties. It is causal in origin and provides a model for the kinematics of quantum theory. Indeterminacy, on the other hand, is statistical in nature and is attributed to the exchange of momentum by time-averaged fields. The need for two limitations on measurability is seen as an extension of the duality principle to measurement theory[[Category:Scientific Paper]] | + | Existing derivations of uncertainty for single particle interactions violate complementarity because they require that the photon exhibit wave and particle behavior simultaneously; and thus singularly. In order to restore physical consistency to quantum theory a model of the photon is proposed having spatial extension equal to the wavelength. As a result uncertainty and indeterminacy must be assigned independent meanings. Uncertainty describes the limit in measurability for instantaneous exchanges of momentum and is due to a photon's particle properties. It is causal in origin and provides a model for the kinematics of quantum theory. Indeterminacy, on the other hand, is statistical in nature and is attributed to the exchange of momentum by time-averaged fields. The need for two limitations on measurability is seen as an extension of the duality principle to measurement theory |
+ | |||
+ | [[Category:Scientific Paper|applying uncertainty principle single particle interactions]] |
Latest revision as of 10:01, 1 January 2017
Scientific Paper | |
---|---|
Title | Applying the Uncertainty Principle to Single Particle Interactions |
Read in full | Link to paper |
Author(s) | Richard Oldani |
Keywords | uncertainty, indeterminacy |
Published | 2004 |
Journal | Physics Essays |
Volume | 17 |
Number | 1 |
No. of pages | 5 |
Read the full paper here
Abstract
Existing derivations of uncertainty for single particle interactions violate complementarity because they require that the photon exhibit wave and particle behavior simultaneously; and thus singularly. In order to restore physical consistency to quantum theory a model of the photon is proposed having spatial extension equal to the wavelength. As a result uncertainty and indeterminacy must be assigned independent meanings. Uncertainty describes the limit in measurability for instantaneous exchanges of momentum and is due to a photon's particle properties. It is causal in origin and provides a model for the kinematics of quantum theory. Indeterminacy, on the other hand, is statistical in nature and is attributed to the exchange of momentum by time-averaged fields. The need for two limitations on measurability is seen as an extension of the duality principle to measurement theory