Collective Atom–Light Interactions in Dense Atomic Vapours [electronic resource] / by James Keaveney.

By:

Keaveney, James [author.]

Contributor(s):

SpringerLink (Online service)

Series: Springer Theses, Recognizing Outstanding Ph.D. ResearchPublisher: Cham : Springer International Publishing : Imprint: Springer, 2014Description: XIII, 144 p. 77 illus., 36 illus. in color. online resourceContent type:

text

Media type:

computer

Carrier type:

online resource

ISBN:

9783319071008

Subject(s):

Genre/Form:

Electronic books.

Additional physical formats: Printed edition:: No titleDDC classification:

535.2 23
537.6 23

LOC classification:

QC350-467
QC630-648

Online resources:

Click here to access online

Contents:

Introduction -- Independent atoms -- Thin cell spectroscopy -- Atom-surface interactions -- Atom-atom interactions -- Giant refractive index -- Fast light in dense thermal vapour -- Fluorescence lifetime -- Coherent dynamics -- Project outlook.

In: Springer eBooksSummary: The propagation of light in 'dense media' where dipole-dipole interactions play a role is a fundamental topic that was first studied in the work of Clausius, Mossotti, Lorenz and Lorentz in the latter half of the nineteenth century. However, until recently there remained some areas of controversy: for example, whereas the Lorentz model for a gas predicts a resonance shift, a discrete dipole model does not. This thesis makes the first combined measurement of both the Lorentz shift and the associated collective Lamb shift. This clear experimental result stimulated new theoretical work that has significantly advanced our understanding of light propagation in interacting media.

Item type:

eBooks

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The propagation of light in 'dense media' where dipole-dipole interactions play a role is a fundamental topic that was first studied in the work of Clausius, Mossotti, Lorenz and Lorentz in the latter half of the nineteenth century. However, until recently there remained some areas of controversy: for example, whereas the Lorentz model for a gas predicts a resonance shift, a discrete dipole model does not. This thesis makes the first combined measurement of both the Lorentz shift and the associated collective Lamb shift. This clear experimental result stimulated new theoretical work that has significantly advanced our understanding of light propagation in interacting media.