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%ما هو (من)٪ 1 - تعريف
![opacity]]) of finding the particle at a given point ''x'' is spread out like a waveform; there is no definite position of the particle. As the amplitude increases above zero the [[curvature]] decreases, so the amplitude decreases again, and vice versa—the result is an alternating amplitude: a wave. Top: [[Plane wave]]. Bottom: [[Wave packet]].](https://commons.wikimedia.org/wiki/Special:FilePath/Propagation of a de broglie wave.svg?width=200 "opacity]]) of finding the particle at a given point ''x'' is spread out like a waveform; there is no definite position of the particle. As the amplitude increases above zero the [[curvature]] decreases, so the amplitude decreases again, and vice versa—the result is an alternating amplitude: a wave. Top: [[Plane wave]]. Bottom: [[Wave packet]].")
![Position ''x'' and momentum ''p'' wavefunctions corresponding to quantum particles. The colour opacity of the particles corresponds to the [[probability density]] of finding the particle with position ''x'' or momentum component ''p''.<br/>
'''Top:''' If wavelength ''λ'' is unknown, so are momentum ''p'', wave-vector ''k'' and energy ''E'' (de Broglie relations). As the particle is more localized in position space, Δ''x'' is smaller than for Δ''p<sub>x</sub>''.<br/>
'''Bottom:''' If ''λ'' is known, so are ''p'', ''k'', and ''E''. As the particle is more localized in momentum space, Δ''p'' is smaller than for Δ''x''.](https://commons.wikimedia.org/wiki/Special:FilePath/Quantum mechanics travelling wavefunctions wavelength.svg?width=200 "Position ''x'' and momentum ''p'' wavefunctions corresponding to quantum particles. The colour opacity of the particles corresponds to the [[probability density]] of finding the particle with position ''x'' or momentum component ''p''.<br/>
'''Top:''' If wavelength ''λ'' is unknown, so are momentum ''p'', wave-vector ''k'' and energy ''E'' (de Broglie relations). As the particle is more localized in position space, Δ''x'' is smaller than for Δ''p<sub>x</sub>''.<br/>
'''Bottom:''' If ''λ'' is known, so are ''p'', ''k'', and ''E''. As the particle is more localized in momentum space, Δ''p'' is smaller than for Δ''x''.")
![two-slit diffraction of waves]], 1803.](https://commons.wikimedia.org/wiki/Special:FilePath/Young Diffraction.png?width=200 "two-slit diffraction of waves]], 1803.")
![Particle impacts make visible the [[interference pattern]] of waves.](https://commons.wikimedia.org/wiki/Special:FilePath/Wave-particle duality.gif?width=200 "Particle impacts make visible the [[interference pattern]] of waves.")
![A quantum particle is represented by a [[wave packet]].](https://commons.wikimedia.org/wiki/Special:FilePath/Wavelet.gif?width=200 "A quantum particle is represented by a [[wave packet]].")
ويكيبيديا
Wave–particle duality is the concept in quantum mechanics that every particle or quantum entity may be described as either a particle or a wave. It expresses the inability of the classical concepts "particle" or "wave" to fully describe the behaviour of quantum-scale objects. As Albert Einstein wrote:
It seems as though we must use sometimes the one theory and sometimes the other, while at times we may use either. We are faced with a new kind of difficulty. We have two contradictory pictures of reality; separately neither of them fully explains the phenomena of light, but together they do.
Through the work of Max Planck, Albert Einstein, Louis de Broglie, Arthur Compton, Niels Bohr, Erwin Schrödinger and many others, current scientific theory holds that all particles exhibit a wave nature and vice versa. This phenomenon has been verified not only for elementary particles, but also for compound particles like atoms and even molecules. For macroscopic particles, because of their extremely short wavelengths, wave properties usually cannot be detected.
Although the use of the wave–particle duality has worked well in physics, the meaning or interpretation has not been satisfactorily resolved; see interpretations of quantum mechanics.
Bohr regarded the "duality paradox" as a fundamental or metaphysical fact of nature. A given kind of quantum object will exhibit sometimes wave, sometimes particle, character, in respectively different physical settings. He saw such duality as one aspect of the concept of complementarity. Bohr regarded renunciation of the cause-effect relation, or complementarity, of the space-time picture, as essential to the quantum mechanical account.
Werner Heisenberg considered the question further. He saw the duality as present for all quantic entities, but not quite in the usual quantum mechanical account considered by Bohr. He saw it in what is called second quantization, which generates an entirely new concept of fields that exist in ordinary space-time, causality still being visualizable. Classical field values (e.g. the electric and magnetic field strengths of Maxwell) are replaced by an entirely new kind of field value, as considered in quantum field theory. Turning the reasoning around, ordinary quantum mechanics can be deduced as a specialized consequence of quantum field theory.
