Observation of atom wave phase shifts induced by van der Waals atom-surface interactions

Observation of atom wave phase shifts induced by van der Waals atom-surface interactions

The development of nanotechnology and atom optics relies on understanding how atoms behave and interact with their environment. Isolated atoms can exhibit wavelike (coherent) behavior with a corresponding de Broglie wavelength and phase which can be affected by nearby surfaces. Here an atom interfer...

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Veröffentlicht in:Physical review letters 2005-09, Vol.95 (13), p.133201.1-133201.4, Article 133201
Hauptverfasser: PERREAULT, John D, CRONIN, Alexander D
Format: Artikel
Sprache:eng
Schlagworte:
Atom and neutron interferometry
Atom and neutron optics
Atomic and molecular collision processes and interactions
Atomic and molecular physics
ATOMS
BEAM OPTICS
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Classical and quantum physics: mechanics and fields
DE BROGLIE WAVELENGTH
Exact sciences and technology
INTERACTIONS
Interactions of atoms, molecules and their ions with surfaces
photon and electron emission
neutralization of ions
INTERFEROMETERS
INTERFEROMETRY
Matter waves
NANOSTRUCTURES
PHASE SHIFT
Physics
Scattering of atoms, molecules and ions
SODIUM
SURFACES
VAN DER WAALS FORCES
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Zusammenfassung:The development of nanotechnology and atom optics relies on understanding how atoms behave and interact with their environment. Isolated atoms can exhibit wavelike (coherent) behavior with a corresponding de Broglie wavelength and phase which can be affected by nearby surfaces. Here an atom interferometer is used to measure the phase shift of Na atom waves induced by the walls of a 50 nm wide cavity. To our knowledge this is the first direct measurement of the de Broglie wave phase shift caused by atom-surface interactions. The magnitude of the phase shift is in agreement with that predicted by Lifshitz theory for a nonretarded van der Waals interaction. This experiment also demonstrates that atom waves can retain their coherence even when atom-surface distances are as small as 10 nm.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.95.133201