De Broglie Waves: Are Electrons Waves or Particles?

Quantum Mechanics for Beginners ◽

10.1093/oso/9780198854227.003.0007 ◽

2020 ◽

pp. 100-120

Author(s):

M. Suhail Zubairy

Keyword(s):

Uncertainty Relation ◽

Subsequent Development ◽

Conclusive Evidence ◽

Einstein Condensation ◽

Heisenberg Uncertainty Relation ◽

Bose Einstein Condensation ◽

De Broglie Waves ◽

Wave Particle Duality ◽

Heisenberg Uncertainty ◽

Bose Einstein

In 1924, de Broglie postulated that particles can behave like waves, thus complementing the observation by Einstein in 1905 that light can behave like particles. This wave–particle duality aspect for both particles and waves had a deep impact on the subsequent development of quantum mechanics. Some highly counterintuitive results, like the Heisenberg uncertainty relation and the Bose–Einstein condensation, that were motivated by wave–particle duality are discussed in this chapter. Following de Broglie’s hypothesis, a wave packet description for a particle is described. An analysis of the Heisenberg microscope is presented, thus motivating the Heisenberg uncertainty relation. The Davisson–Germer experiment that showed that electrons can behave like waves and the Compton effect that provided early conclusive evidence that light can behave like particles are also discussed.

Download Full-text

Some properties of the world crystal in fractal spacetime theory.

Australian Journal of Physics ◽

10.1071/ph99022 ◽

2000 ◽

Vol 53 (2) ◽

pp. 231 ◽

Cited By ~ 2

Author(s):

M. Agop ◽

I. Oprea ◽

C. Sandu ◽

R. Vlad ◽

C. Gh. Buzea ◽

...

Keyword(s):

Uncertainty Relation ◽

Background Field ◽

Heisenberg Uncertainty Relation ◽

Wave Particle Duality ◽

The World ◽

Heisenberg Uncertainty ◽

Spacetime Theory

We prove that the wave-particle duality, inertia and the Heisenberg uncertainty relation are properties of a fractal spacetime, self-structured by a gravitomagnetic background field, in the world crystal.

Download Full-text

Is FeSe a superconductor in the Bose-Einstein condensation limit?

10.36471/jccm_november_2017_01 ◽

2017 ◽

Keyword(s):

Einstein Condensation ◽

Bose Einstein Condensation ◽

Bose Einstein

Download Full-text

Systems with Condensates and Pairing

10.1093/oso/9780198797241.003.0012 ◽

2018 ◽

Author(s):

Klaus Morawetz

Keyword(s):

Critical Parameters ◽

Einstein Condensation ◽

Cooper Pairs ◽

Pair Breaking ◽

Systematic Theory ◽

Bose Einstein Condensation ◽

T Matrix ◽

The Stability ◽

Bose Einstein

The Bose–Einstein condensation and appearance of superfluidity and superconductivity are introduced from basic phenomena. A systematic theory based on the asymmetric expansion of chapter 11 is shown to correct the T-matrix from unphysical multiple-scattering events. The resulting generalised Soven scheme provides the Beliaev equations for Boson’s and the Nambu–Gorkov equations for fermions without the usage of anomalous and non-conserving propagators. This systematic theory allows calculating the fluctuations above and below the critical parameters. Gap equations and Bogoliubov–DeGennes equations are derived from this theory. Interacting Bose systems with finite temperatures are discussed with successively better approximations ranging from Bogoliubov and Popov up to corrected T-matrices. For superconductivity, the asymmetric theory leading to the corrected T-matrix allows for establishing the stability of the condensate and decides correctly about the pair-breaking mechanisms in contrast to conventional approaches. The relation between the correlated density from nonlocal kinetic theory and the density of Cooper pairs is shown.

Download Full-text