Non-Classical Behavior of Atoms in an Interferometer

, &
Foundations of Physics 32 (9):1329-1346 (2002)
  Copy   BIBTEX

Abstract

Using the time-dependent wave function we have studied the properties of the atomic transverse motion in an interferometer, and the cause of the non-classical behavior of atoms reported by Kurtsiefer, Pfau, and Mlynek [Nature 386, 150 (1997)]. The transverse wave function is derived from the solution of the two-dimensional Schrödinger's equation, written in the form of the Fresnel–Kirchhoff diffraction integral. It is assumed that the longitudinal motion is classical. Comparing data of the space distribution and of the transverse momentum distribution in interferometers with one and two open slits, it follows that the atomic motion is influenced by the atomic matter wave and violates the laws of classical mechanics. However, the negative values of Wigner's function should not be taken as evidence that the atoms in an interferometer violate the classical statistical law of the addition of positive probabilities. This inference follows from the comparison of properties of Wigner's function and of the de Broglian probability density in phase space

Categories

Keywords

Reprint years

DOI

10.1023/a:1020365405788

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,219

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Exact quantum-statistical dynamics of time-dependent generalized oscillators.Don Page - manuscript
Measurement of quantum states and the Wigner function.Antoine Royer - 1989 - Foundations of Physics 19 (1):3-32.
Meaning of the wave function.Shan Gao - 2010
The Wigner Function as Distribution Function.M. Revzen - 2006 - Foundations of Physics 36 (4):546-562.
Quasi-probability distributions for arbitrary spin-j particles.G. Ramachandran, A. R. Usha Devi, P. Devi & Swarnamala Sirsi - 1996 - Foundations of Physics 26 (3):401-412.
Quantum Model of Classical Mechanics: Maximum Entropy Packets. [REVIEW]P. Hájíček - 2009 - Foundations of Physics 39 (9):1072-1096.
The Wigner phase-space description of collision processes.Hai-Woong Lee & Marlan O. Scully - 1983 - Foundations of Physics 13 (1):61-72.
Quantum probability and unified approach to quantization and dynamics.Blagowest A. Nikolov - 1996 - Foundations of Physics 26 (2):257-269.
A resolution of the classical wave-particle problem.J. P. Wesley - 1984 - Foundations of Physics 14 (2):155-170.
Area in phase space as determiner of transition probability: Bohr-Sommerfeld bands, Wigner ripples, and Fresnel zones. [REVIEW]W. Schleich, H. Walther & J. A. Wheeler - 1988 - Foundations of Physics 18 (10):953-968.
On the indistinguishability of classical particles.S. Fujita - 1991 - Foundations of Physics 21 (4):439-457.
Statistical mechanics and the ontological interpretation.D. Bohm & B. J. Hiley - 1996 - Foundations of Physics 26 (6):823-846.
Ehrenfest's theorem reinterpreted and extended with Wigner's function.Antoine Royer - 1992 - Foundations of Physics 22 (5):727-736.
Correspondence between the classical and quantum canonical transformation groups from an operator formulation of the wigner function.Leehwa Yeh & Y. S. Kim - 1994 - Foundations of Physics 24 (6):873-884.
Stochastic electrodynamics. I. On the stochastic zero-point field.G. H. Goedecke - 1983 - Foundations of Physics 13 (11):1101-1119.

Analytics

Added to PP
2013-12-01

Downloads
61 (#254,961)

6 months
2 (#1,182,310)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

No citations found.

Add more citations

References found in this work

Add more references