Precision interferometry in a new shape : higher-order Laguerre-Gauss modes for gravitational wave detection /

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Bibliographic Details
Author / Creator:Fulda, Paul, author.
Imprint:Cham : Springer, [2013?]
©2014
Description:1 online resource.
Language:English
Series:Springer theses
Springer theses.
Subject:
Format: E-Resource Dissertations Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/11080644
Hidden Bibliographic Details
ISBN:9783319013756
3319013750
3319013742
9783319013749
9783319013749
Notes:Includes bibliographical references.
Print version record.
Summary:With his Ph. D. thesis, presented here in the format of a "Springer Theses", Paul Fulda won the 2012 GWIC thesis prize awarded by the Gravitational Wave International Committee. The impact of thermal noise on future gravitational wave detectors depends on the size and shape of the interrogating laser beam. It had been known since 2006 that, in theory, higher-order Laguerre-Gauss modes could reduce thermal noise. Paul Fuldas research brings Laguerre-Gauss modes an enormous step forward. His work includes analytical, numerical and experimental work on table-top setups as well as experiments at the Glasgow 10m prototype interferometer. Using numerical simulations the LG33 mode was selected as the optical mode to be tested. Further research by Paul and his colleagues since then concentrated on this mode. Paul has developed and demonstrated simple and effective methods to create this mode with diffractive optics and successfully demonstrated its compatibility with the essential building blocks of gravitational wave detectors, namely, optical cavities, Michelson interferometers and opto-electronic sensing and control systems. Through this work, Laguerre-Gauss modes for interferometers have been transformed from an essentially unknown entity to a well understood option with an experimental basis.
Other form:Print version: Fulda, Paul. Precision interferometry in a new shape 9783319013749
Standard no.:10.1007/978-3-319-01375-6