Physics
Textbooks
Boundless Physics
Introduction to Quantum Physics
History and Quantum Mechanical Quantities
Physics Textbooks Boundless Physics Introduction to Quantum Physics History and Quantum Mechanical Quantities
Physics Textbooks Boundless Physics Introduction to Quantum Physics
Physics Textbooks Boundless Physics
Physics Textbooks
Physics
Concept Version 6
Created by Boundless

Particle-Wave Duality

Wave–particle duality postulates that all physical entities exhibit both wave and particle properties.

Learning Objective

  • Describe experiments that demonstrated wave-particle duality of physical entities


Key Points

    • All entities in Nature behave as both a particle and a wave, depending on the specifics of the phenomena under consideration.
    • Particle-wave duality is usually hidden in macroscopic phenomena, conforming to our intuition.
    • In the double-slit experiment of electrons, individual event displays a particle-like property of localization (or a "dot"). After many repetitions, however, the image shows an interference pattern, which indicates that each event is in fact governed by a probability distribution.

Terms

  • Maxwell's equations

    A set of equations describing how electric and magnetic fields are generated and altered by each other and by charges and currents.

  • black body

    An idealized physical body that absorbs all incident electromagnetic radiation, regardless of frequency or angle of incidence. Although black body is a theoretical concept, you can find approximate realizations of black body in nature.

  • photoelectric effects

    In photoelectric effects, electrons are emitted from matter (metals and non-metallic solids, liquids or gases) as a consequence of their absorption of energy from electromagnetic radiation.


Full Text

Wave–particle duality postulates that all physical entities exhibit both wave and particle properties. As a central concept of quantum mechanics, this duality addresses the inability of classical concepts like "particle" and "wave" to fully describe the behavior of (usually) microscopic objects.

From a classical physics point of view, particles and waves are distinct concepts. They are mutually exclusive, in the sense that a particle doesn't exhibit wave-like properties and vice versa. Intuitively, a baseball doesn't disappear via destructive interference, and our voice cannot be localized in space. Why then is it that physicists believe in wave-particle duality? Because that's how mother Nature operates, as they have learned from several ground-breaking experiments. Here is a short, chronological list of those experiments:

  • Young's double-slit experiment: In the early Nineteenth century, the double-slit experiments by Young and Fresnel provided evidence that light is a wave. In 1861, James Clerk Maxwell explained light as the propagation of electromagnetic waves according to the Maxwell's equations.
  • Black body radiation: In 1901, to explain the observed spectrum of light emitted by a glowing object, Max Planck assumed that the energy of the radiation in the cavity was quantized, contradicting the established belief that electromagnetic radiation is a wave.
  • Photoelectric effect: Classical wave theory of light also fails to explain photoelectric effect. In 1905, Albert Einstein explained the photoelectric effects by postulating the existence of photons, quanta of light energy with particulate qualities.
  • De Broglie's wave (matter wave): In 1924, Louis-Victor de Broglie formulated the de Broglie hypothesis, claiming that all matter, not just light, has a wave-like nature. His hypothesis was soon confirmed with the observation that electrons (matter) also displays diffraction patterns, which is intuitively a wave property, as shown in .

From these historic achievements, physicists now accept that all entities in nature behave as both a particle and a wave, depending on the specifics of the phenomena under consideration. Because of its counter-intuitive aspect, the meaning of the particle-wave duality is still a point of debate in quantum physics. The standard interpretation is that the act of measurement causes the set of probabilities, governed by a probability distribution function acquired from a "wave", to immediately and randomly assume one of the possible values, leading to a "particle"-like result.

So, why do we not notice a baseball acting like a wave? The wavelength of the matter wave associated with a baseball, say moving at 95 miles per hour, is extremely small compared to the size of the ball so that wave-like behavior is never noticeable.

[ edit ]
Edit this content
Prev Concept
Implications of Quantum Mechanics
Diffraction Revisited
Next Concept
Subjects
  • Accounting
  • Algebra
  • Art History
  • Biology
  • Business
  • Calculus
  • Chemistry
  • Communications
  • Economics
  • Finance
  • Management
  • Marketing
  • Microbiology
  • Physics
  • Physiology
  • Political Science
  • Psychology
  • Sociology
  • Statistics
  • U.S. History
  • World History
  • Writing

Except where noted, content and user contributions on this site are licensed under CC BY-SA 4.0 with attribution required.